Tek DPO, MSO 4000 Series Performance
Contents
1. Performance checks Vertical scale Vertical offset 1 Low limit Test result High limit models Channel 1 DC Offset 1 mV div 900 mV 895 0 mV 905 0 mV Accuracy 1 mV div 900 mV 905 0 mV 895 0 mV 20 MHz BW 50 Q 2 mV div 500 mV 497 0 mV 503 0 mV 2 mV div 500 mV 503 0 mV 497 0 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 mV 100 mV div 5 0 V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V Channel 1 DC Offset 1 mV div 900 mV 895 2 mV 904 8 mV Accuracy 1 mV div 900 mV 904 8 mV 895 2 mV 20 MHz BW 1 2 mV div 500 mV 497 1 mV 502 9 mV 2 mV div 500 mV 502 9 mV 497 1 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 5 0 V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V 1 01 V div 99 5 V 98 80 V 100 2 V 1 01 V div 99 5 V 100 2 V 98 80 V Channel 2 DC Offset 1 mV div 900 mV 895 0 mV 905 0 mV Accuracy 1 mV div 900 mV 905 0 mV 895 0 mV 20 MHz BW 50 Q 2 mV div 500 mV 497 0 mV 503 0 mV 2 mV div 500 mV 503 0 mV 497 0 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 5 0 V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V Channel 2 DC Offset 1 mV div 900 mV 895 2 mV 904 8 mV Accuracy 1 mV div 900 mV 904 8 mV 895 2 mV 20 MHz BW 1 MQ 2 mV div 500 mV 497 1 mV 502 9 mV 2 mV div 500 mV 502 9 mV 497 1 mV2. ANO S E L1E 7 dD jon 0 25Xtsampterate TBA s 3ps 1 x RecordDuration 4 KE X treading Assumes that error due to aliasing is insignificant The term under the square root sign is the stability and is due to TIE Time Interval Error The errors due to this term occur throughout a single shot measurement The second term is due to both the absolute center frequency accuracy and the center frequency stability of the timebase and varies between multiple single shot measurements over the observation interval the amount of time from the first single shot measurement to the final single shot measurement 1 For 50 path 1 V div is the maximum vertical setting 1 6 MS04000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 2 Digital channel input specifications MSO4000 only Characteristic Description Threshold voltage range 2 V to 5 V V Digital threshold accuracy 100 mV 3 of the threshold setting after calibration Timing resolution 2 ns for the main memory and 60 6 ps for MagniVu memory Table 1 3 Horizontal and acquisition system specifications Characteristic V Long term sample rate and delay time accuracy Seconds Division range Record Length 1K 10 K 100 K 1M 10 M Description 5 ppm over any 21 ms time interval DPO4054 DPO4034 DPO4032 DPO4104 MSO4104 MSO4054 MSO4034 MSO4032 400 ps 405 1ns 40s 400
3. Ethernet interface Standard on all models 10 100 Mbps USB interface 1 Device and 3 Host connectors all models GPIB interface Available as an optional accessory that connects to USB Device and USB Host port with the TEK USB 488 GPIB to USB Adapter Control interface is incorporated in the instrument user interface Video signal output Probe compensator output voltage and frequency typical A 15 pin XGA RGB type connector Output voltage 0 V to 2 5 V 1 behind 1 2 Frequency 1 kHz 5 Trigger Auxiliary output AUX OUT LOW TRUE LOW to HIGH transition indicates that the trigger occurred The logic levels are Characteristic Limits Vout HI 22 5 V open circuit 21 0 V into a 50 load to ground Vout LO 0 7 V into a load of lt 4 mA 0 25 V into a 50 load to ground Table 1 7 Power source specifications Characteristic Description Source voltage 100 V to 240 V 10 Source frequency 90 V to 264 V 47 Hz to 66 Hz 100 V to 132 V 360 Hz to 440 Hz Fuse rating T6 3AH 250 V The fuse is not customer replaceable MSO4000 and DPO4000 Series Specifications and Performance Verification 1 13 Specifications Table 1 8 Data storage specifications Characteristic Description Nonvolatile memory retention time No time limit for front panel settings saved waveforms setups and calibration constants typical Real time cloc
4. Standard serial bus interface triggering PC Address Triggering 7 and 10 bit user specified address as well as General Call START byte HS mode EEPROM and CBUS Data Trigger 1 to 5 bytes of user specified data Trigger On Start Repeated Start Stop Missing Ack Data or Address and Data Maximum Data Rate 10 Mbps SPI Data Trigger 1 to 16 bytes of user specified data Trigger On SS Active Start of Frame MOSI MISO or MOSI and MISO Maximum Data Rate 10 Mbps CAN Data Trigger 1 to 8 bytes of user specified data including qualifiers of equal to not equal to lt gt less than greater than gt less than or equal to lt greater than or equal to gt Trigger On Start of Frame Type of Frame Identifier Data Identifier and Data End of Frame Missing Ack or Bit Stuffing Error Frame Type Data Remote Error Overload Identifier Standard 11 bit and Extended 29 bit identifiers Maximum Data Rate 1 Mbps RS 232 Trigger On Tx Start Bit Rx Start Bit Tx End of Packet Rx End of Packet Tx Data Rx Data Tx Parity Error or Rx Parity Error Maximum Data Rate 10 Mbps LIN 4 Identifier Trigger 6 bits of user specified data equal to Data Trigger 1 to 8 bytes of user specified data including qualifiers of equal to not equal to lt gt less than lt greater than gt less than or equal to lt greater than or equal to gt inside range or o
5. 7 Worldwide visit www tektronix com to find contacts in your area Table of Contents General edd eelere iii Specifications ene EE 1 1 Performance Verification Performance Verification EEN Ente t ERE ERR EEN e Vire dU a S Ente de celeste 2 1 Upgrade the Firmware 2 2 Test 2 3 Performance Verification Drocedures 2 19 MSO4000 and DPO4000 Series Specifications and Performance Verification 1 Table of Contents List of Tables ii Table 1 1 Analog channel input and vertical specifications essen 1 1 Table 1 2 Digital channel input specifications MSO4000 on 1 7 Table 1 3 Horizontal and acquisition system 1 7 Table 1 4 Trigger specification S s eoor ertir cece Ime meme messe ne nnns 1 7 Table 1 5 Display specifications eee eme mesh esee 1 13 Table 1 6 Input Output port 5 eee nee eee menm menn 1 13 Table 1 7 Power source specifications ccc cece eee me eme emen esee
6. 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 50V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V 1 01 V div 99 5 V 98 80 V 100 2 V 1 01 Vidiv 99 5 V 100 2 V 98 80 V 2 10 MSO4000 and DPO4000 Series Specifications and Performance Verification DC Offset Accuracy Performance Verification Performance checks Vertical scale Vertical offset Low limit Test result High limit DPO4104 DPO4054 DPO4034 MSO4104 MS04054 MSO4034 Channel 3 DC Offset 1 mV div 900 mV 895 0 mV 905 0 mV Accuracy 1 mV div 900 mV 905 0 mV 895 0 mV 20 MHz BW 50 Q 2 mVidiv 500 mV 497 0 mV 503 0 mV 2 mVidiv 500 mV 503 0 mV 497 0 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 5 0 V 4 955 V 5 045 V 100 mV div 5 0 V 5 04 5 V 4 955 V Channel 3 DC Offset 1 mV div 900 mV 895 2 mV 904 8 mV Accuracy 1 mV div 900 mV 904 8 mV 895 2 mV 20 MHz BW 1 MO 2 mV div 500 mV 497 1 mV 502 9 mV 2 mVidiv 500 mV 502 9 mV 497 1 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 5 0V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V 1 01 Vidiv 99 5 V 98 80 V 100 2 V 1 01 Vidiv 99 5 V 100 2 V 98 80 V Channel 4 DC Offset 1 mV div 900 mV 895 0 mV 905 0 mV Accuracy 1 mV div 900 mV 905 0 mV 895 0 mV 20 MHz BW 50 Q 2 mVidiv 500 mV 497 0 mV 503
7. Channel 3 Full 7 433 6 0723 250 MHz 5 099 3 7496 20 MHz 3 320 3 3128 Channel 4 Full 7 433 6 0723 250 MHz 5 099 3 7496 20 MHz 3 320 3 3128 DPO4054 MS04054 Channel 1 Full 7 730 3 7779 250 MHz 5 296 3 3567 20 MHz 3 822 3 3136 Channel 2 Full 7 730 3 7779 250 MHz 5 296 3 3567 20 MHz 3 822 3 3136 Channel 3 Full 7 730 3 7779 250 MHz 5 296 3 3567 20 MHz 3 822 3 3136 Channel 4 Full 7 730 3 7779 250 MHz 5 296 3 3567 20 MHz 3 822 3 3136 DPO4034 MS04034 2 12 MS04000 and DPO4000 Series Specifications and Performance Verification Performance Verification Random Noise Sample Acquisition Mode Vertical sensitivity 100 mV div Performance checks 1 MO 50 Q Bandwidth Test result mV High limit mV Test result mV High limit mV Channel 1 Full 6 539 3 3777 250 MHz 4 894 3 2766 20 MHz 3 4223 3 1160 Channel 2 Full 6 539 3 3777 250 MHz 4 894 3 2766 20 MHz 3 4223 3 1160 Channel 3 Full 6 539 3 3777 250 MHz 4 894 3 2766 20 MHz 3 4223 3 1160 Channel 4 Full 6 539 3 3777 250 MHz 4 894 3 2766 20 MHz 3 4223 3 1160 DPO4032 MSO4032 Channel 1 Full 7 341 3 1816 250 MHz 4 9879 3 9738 20 MHz 3 1185 3 6127 Channel 2 Full 7 341 3 1816 250 MHz 4 9879 3 9738 20 MHz 3 1185 3 6127 MSO4000 and DPO4000 Series Specifications and Performance Verification 2 13 Performance Verification Delta Time Measurement Accuracy Channel 1 MSO DPO 4 ns Div Source freq 240 MHz MSO DPO V
8. Depth 137 mm 5 4 in from feet to front of knobs 145 mm 5 7 in from feet to front of front cover Nominal rack mount 5U rack sizes Height 218 mm 8 6 in Width 488 mm 19 2 in from outside of handle to outside of handle Depth 559 mm 22 0 in from outside of handle to back of slide Weight 5 1 kg 11 3 lbs stand alone instrument without front cover 8 7 kg 19 1 Ibs instrument with rack mount without front cover 9 5 kg 21 0 Ibs when packaged for domestic shipment and without rack mount Clearance Requirements The clearance requirement for adequate cooling is 50 8 mm 2 in on the left side when looking at the front of the instrument and on the rear of the unit MSO4000 and DPO4000 Series Specifications and Performance Verification 1 15 Specifications Table 1 11 P6516 Digital Probe specifications Characteristic Description Number of channels 16 Threshold accuracy 100 mV 3 of threshold Maximum signal swing 6 0 V peak to peak centered around the threshold voltage Minimum signal swing 500 mV peak to peak Input resistance 20 Input capacitance 3 0 pF typical Temperature Operating 0 C to 50 C 32 F to 122 F Nonoperating 55 C to 75 C 67 F to 167 F Altitude Operating 4 500 m 15 000 ft Nonoperating 15 000 m 50 000 ft Pollution Degree 2 indoor use only Humidity 10 to 95 relative humidity 1 16 MS04000 and DPO4000 Ser
9. 0 mV 2 mVidiv 500 mV 503 0 mV 497 0 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 5 mV 100 mV div 5 0V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V Channel4 DC Offset 1 mV div 900 mV 895 2 mV 904 8 mV Accuracy 1 mV div 900 mV 904 8 mV 895 2 mV 20 MHz BW 1 MO 2 mV div 500 mV 497 1 mV 502 9 mV 2 mVidiv 500 mV 502 9 mV 497 5 mV 10 mV div 500 mV 495 5 mV 504 5 mV 10 mV div 500 mV 504 5 mV 495 1 mV 100 mV div 5 0V 4 955 V 5 045 V 100 mV div 5 0 V 5 045 V 4 955 V 1 01 Vidiv 99 5 V 98 80 V 100 2 V 1 01 Vidiv 99 5 V 100 2 V 98 80 V 1 Use this value for both the calibrator output and the oscilloscope offset setting MSO4000 and DPO4000 Series Specifications and Performance Verification Performance Verification Performance checks Low limit Test result High limit Sample Rate and Delay Time Accuracy 1 divisions 1 divisions Auxiliary Trigger Output Trigger Output High 1 MO 225V Low 1 MQ s07V Trigger Output High 50 Q 10 Sg Low 50 Q 0 25 V Random Noise Sample Acquisition Mode Vertical sensitivity 100 mV div Performance checks 1 MQ 50 0 Bandwidth Test result mV High limit mV Test result mV High limit mV DPO4104 MS04104 Channel 1 Full 7 433 6 0723 250 MHz 5 099 3 7496 20 MHz 3 320 3 3128 Channel 2 Full 7 433 6 0723 250 MHz 5 099 3 7496 20 MHz 3 320 3 3128
10. 1 13 Table 1 8 Data storage specifications cece eee mese meses 1 14 Table 1 9 Environmental specifications ee eme mene mese 1 14 Table 1 10 Mechanical 5 ccc cece cece cence eee meme menm menn 1 15 Table 1 11 P6516 Digital Probe specifications cece cece ee en nee eee enna me eee 1 16 Table 2 1 Maximum Bandwidth Frequency 1 2 23 Table 2 2 Gain Expected worksheet 00 ccc cece cece eee nee e eee mesh meses 2 26 4000 and DPO4000 Series Specifications and Performance Verification General Safety Summary General Safety Summary Review the following safety precautions to avoid injury and prevent damage to this product or any products connected to it To avoid potential hazards use this product only as specified Only qualified personnel should perform service procedures To Avoid Fire or Personal Use Proper Power Cord Use only the power cord specified for this product and Injury certified for the country of use Connect and Disconnect Properly Do not connect or disconnect probes or test leads while they are connected to a voltage source Ground the Product This product is grounded through the grounding conductor of the power cord To avoid electric
11. 1 5 1 5 2 8 5 4000 and DPO4000 Series Specifications and Performance Verification Performance Verification DC Gain Accuracy Performance checks Vertical scale Low limit Test result High limit Channel 3 DC Gain 1 mV div 1 5 1 5 Accuracy 0 V offset 27 mv div 1 5 1 5 0 V vertical position 20 MHz BW 1 MQ 4 98 mV div 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 Vidiv 1 5 1 5 Channel 4 DC Gain 1 mV div 1 5 1 5 Accuracy 0 V offset 2 mia 1 5 1 5 0 V vertical position 20 MHz BW 50 Q 4 98 mV 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 0 V div 1 5 1 5 Channel 4 DC Gain 1 mV div 1 5 1 5 Accuracy 0 V offset 2 mia 1 5 1 5 0 V vertical position 20 MHz BW 1 MQ 4 98 mV div 3 096 3 096 5 mV div 1 5 1 5 10 mV div 1 596 1 596 20 mVidiv 1 596 1 596 49 8 mV 3 096 3 096 50 mV div 1 5 1 5 100 mV div 1 596 1 596 200 mV div 1 596 1 596 500 mV div 1 5 1 5 1 Vidiv 1 5 1 5 5 4000 and DPO4000 Series Specifications and Performance Verification 2 9 Performance Verification DC Offset Accuracy
12. 55 ps 100 mV 800 mV 46 ps 500 mV 4V 45 ps 1V 4V 86 ps MSO DPO 40 ns Div Source freq 24 MHz 1mV 8 mV 940 ps 5 mV 40 mV 530 ps 100 mV 800 mV 430 ps 500 mV 4V 430 ps 1V 4V 850 ps MSO DPO 400 ns Div Source freq 2 4 MHz 1mV 8 mV 94 ns 5 mV 40 mV 5 3 ns 100 mV 800 mV 4 3 ns 500 mV 4V 4 3 ns 1V 4V 8 5 ns MSO DPO 4 us Div Source freq 240 kHz 1 mV 8 mV 94 ns 5 mV 40 mV 53 ns 100 mV 800 mV 43 ns 500 mV 4V 43 ns 1V 4V 85 ns MSO DPO 40 us Div Source freq 24 kHz 1mV 8 mV 940 ns 5 mV 40 mV 530 ns 100 mV 800 mV 430 ns 500 mV 4V 430 ns 1V 4V 850 ns MSO DPO 400 us Div Source freq 2 4 kHz 1mV 8 mV 9 4 us 5 mV 40 mV 5 3 us 100 mV 800 mV 4 3 us 500 mV 4V 4 3 us 1V 4V 8 5 us 1 Channels 3 and 4 are only on four channel oscilloscopes MS04000 and DPO4000 Series Specifications and Performance Verification 2 17 Performance Verification Performance checks Digital Threshold Accuracy MSO4000 series only Digital channel Threshold V V Low limit Test result High limit DO 0v 0 1 V 0 1 V 4V 3 78 V 4 22 V D1 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D2 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D3 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D4 0v 0 1 V 0 1 V 4V 3 78 V 4 22 V D5 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D6 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D7 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D8 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D9 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D10
13. DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D11 0v 0 1 V 0 1 V 4V 3 78 V 4 22 V D12 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V D13 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D14 OV 0 1 V 0 1 V 4V 3 78 V 4 22 V D15 DV 0 1 V 0 1 V 4V 3 78 V 4 22 V 2 18 MSOA4000 and DPO4000 Series Specifications and Performance Verification Performance Verification Performance Verification Procedures The following three conditions must be met prior to performing these procedures 1 The oscilloscope must have been operating continuously for twenty 20 minutes in an environment that meets the operating range specifications for temperature and humidity You must perform a signal path compensation SPC See Signal Path Compensation in the Tektronix 4000 Series Digital Phosphor Oscilloscopes User Manual the operating temperature changes by more than 10 C 18 F you must perform the signal path compensation again You must connect the oscilloscope and the test equipment to the same AC power circuit Connect the oscilloscope and test instruments into a common power strip if you are unsure of the AC power circuit distribution Connecting the oscilloscope and test instruments into separate AC power circuits can result in offset voltages between the equipment which can invalidate the performance verification procedure The time required to complete the entire procedure is approximately one hour d WARNING Some procedures use hazardous voltages To prevent electr
14. Div Source Nu Test result High limit 5 mV 40 mV 55 ps 100 mV 800 mV 46 ps 500 mV 4V 45 ps 1V 4V 86 ps MSO DPO 40 ns Div Source freq 24 MHz 1mV 8 mV 940 ps 5 mV 40 mV 530 ps 100 mV 800 mV 430 ps 500 mV 4V 430 ps 1V 4V 850 ps MSO DPO 400 ns Div Source freq 2 4 MHz 1mV 8 mV 9 4 ns 5 mV 40 mV 5 3 ns 100 mV 800 mV 4 3 ns 500 mV 4V 4 3 ns 1V 4V 8 5 ns MSO DPO 4 us Div Source freq 240 kHz 1mV 8 mV 94 ns 5mV 40 mV 53 ns 100 mV 800 mV 43 ns 500 mV 4V 43 ns 1V 4V 85 ns MSO DPO 40 us Div Source freq 24 kHz 1mV 8 mV 940 ns 5 mV 40 mV 530 ns 100 mV 800 mV 430 ns 500 mV 4V 430 ns 1V 4V 850 ns MSO DPO 400 us Div Source freq 2 4 kHz 1mV 8 mV 9 4 us 5mV 40 mV 5 3 us 100 mV 800 mV 4 3 us 500 mV 4V 4 3 us 1V 4V 8 5 us 2 14 MS04000 and DPO4000 Series Specifications and Performance Verification Performance Verification Delta Time Measurement Accuracy Channel 2 MSO DPO 4 ns Div Source freq 240 MHz MSO DPO V Div Source No Test result High limit 5 mV 40 mV 55 ps 100 mV 800 mV 46 ps 500 mV 4V 45 ps 1V 4V 86 ps MSO DPO 40 ns Div Source freq 24 MHz 1mV 8 mV 940 ps 5 mV 40 mV 530 ps 100 mV 800 mV 430 ps 500 mV 4V 430 ps 1V 4V 850 ps MSO DPO 400 ns Div Source freq 2 4 MHz 1mV 8 mV 94 ns 5 mV 40 mV 5 3 ns 100 mV 800 mV 4 3 ns 500 mV 4V 4 3 ns 1V 4V 8 5 ns MSO DPO 4 us Div Source freq 240 kHz 1 mV 8 mV 94 ns 5 mV 40 mV 53 ns 100 mV 800 mV 43 ns 500 mV 4V 43 ns 1V 4V 85 ns MSO DPO 40 u
15. MSO4000 and DPO4000 Series Specifications and Performance Verification iii General Safety Summary Terms in this Manual Symbols and Terms on the Product iv These terms may appear in this manual WARNING Warning statements identify conditions or practices that could result in injury or loss of life CAUTION Caution statements identify conditions or practices that could result in damage to this product or other property These terms may appear on the product DANGER indicates an injury hazard immediately accessible as you read the marking WARNING indicates an injury hazard not immediately accessible as you read the marking B CAUTION indicates a hazard to property including the product The following symbol s may appear on the product A x CAUTION Protective Ground Mains Connected Refer to Manual Earth Terminal Chassis Ground ON Power ILL On Off MSOA4000 and DPO4000 Series Specifications and Performance Verification Specifications Specifications This chapter contains specifications for the DPO4000 and the MSO4000 series oscilloscopes All specifications are guaranteed unless noted as typical Typical specifications are provided for your convenience but are not guaranteed Specifications that are marked with the symbol are checked in Performance Verification All specifications apply to all DPO4000 and MSO4000 models unless noted otherwise To meet specifications two c
16. a triggered display 11 Adjust the Horizontal POSITION knob to move the trigger location to the center of the screen 50 12 Turn the Horizontal POSITION knob counterclockwise to set the delay to exactly 80 ms 13 Set the Horizontal Scale to 400 ns div 14 Compare the rising edge of the marker with the center horizontal graticule line The rising edge should be within 1 divisions of center graticule Enter the deviation in the test record NOTE One division of displacement from graticule center corresponds to a 5 ppm time base error Check Trigger Out This test checks the Trigger Output 1 Connect the Trigger Out signal from the rear of the instrument to the channel 1 input using a 50 Q cable WW Ch 1 Oscilloscope 0 6 fo 6 Trigger out 2 Push the front panel Default Setup button to set the instrument to the factory default settings 3 Push the channel 1 button gt Set the oscilloscope impedance to 1 MQ The default Impedance setting is IMQ Set the horizontal to 4 uS div and the vertical to 1 V div Push the front panel Wave Inspector Measure button Push the Add Measurement lower bezel button Use the Multipurpose a knob to select the Low measurement e Se u Push the OK Add Measurement side bezel button MSO4000 and DPO4000 Series Specifications and Performance Verification 2 29 Performance Verification Check Random Noise Sample Acq
17. all front panel inputs including Aux In Aux In only provides 1 MO input impedance and does not offer 50 Q as do the other input channels Total probe power DPO4032 DPO4034 DPO4054 MS04032 MSO4034 MSO4054 50 W DPO4104 MSO4104 50 W with a derating of 0 8 W C for ambient temperatures 225 C Probe power per channel Voltage Max Amperage Voltage Tolerance 5V 50 mA 250 mW 5 12 V 2 A 24 W 10 Number of digitized bits 8 bits Displayed vertically with 25 digitization levels DL per division 10 24 divisions dynamic range DL is the abbreviation for digitization level A DL is the smallest voltage level change that can be resolved by an 8 bit A D Converter This value is also known as the LSB least significant bit Sensitivity range coarse 1 MO 500 1 mV div to 10 V div in a 1 2 5 sequence 1 mV div to 1 V div in a 1 2 5 sequence Sensitivity range fine Sensitivity resolution fine typical 1 mV div to 5 Vidiv lt 50 to gt 50 of selected setting 1 MO 10 Vidiv lt 50 to 0 1M Q 1 mV div to 500 mV div lt 50 to gt 50 of selected setting 50 1 Vidiv lt 50 to 0 50 Allows continuous adjustment from 1 mV div to 10 V div 1 MQ Allows continuous adjustment from 1 mV div to 1 V div 50 lt 1 of current setting Position range 5 divisions Analog bandwidth 500 The limits stated below are for ambient temperature of lt 30 C and the ba
18. at the selected vertical scale with a set frequency of 50 kHz For example at 5 mV div use a MS04000 and DPO4000 Series Specifications and Performance Verification 10 1 12 19 14 15 Performance Verification gt 40 mV signal at 2 mV div use a 216 mV signal at 1 mV div use a 28 mV signal Use a sine wave for the signal source Turn the Horizontal Scale knob to 10 ms division Push the front panel Wave Inspector Measure button and the lower bezel Add Measurement button Use the Multipurpose a knob to select the Peak to Peak measurement Push the OK Add Measurement side bezel button This will provide you with a mean V of the signal Call this reading Ha Record the value of H for example 816 mV in the test record Turn the Horizontal Scale knob to 1 ns division Adjust the signal source to the maximum bandwidth frequency for the bandwidth and model desired as shown in worksheet below Measure Vp p of the signal on the oscilloscope using statistics as in the previous step to get the mean V Call this reading V Record the value of V in the test record NOTE For more information on the contents of this worksheet refer to the bandwidth specifications See Table 1 1 on page 1 1 Table 2 1 Maximum Bandwidth Frequency worksheet Model DPO4104 MSO4104 Impedance Vertical Scale Maximum bandwidth 500 5 mVidiv 1 GHz 500 2 mVidiv 350 MHz 500
19. calibrator impedances are both set to 50 Q Push the Impedance lower bezel button to select 50 Q Set the calibrator to the vertical offset value shown in the test record for example 900 mV for a 1 mV div setting Set the calibrator to the same impedance as you set for the oscilloscope Set the oscilloscope to the vertical offset value shown in the test record for example 900 mV for a 1 mV div setting Turn the vertical Scale to match the value in the test record for example 1 mV div Turn the Horizontal Scale knob to 1 ms div Push the lower bezel Bandwidth button Push the side bezel button to select the bandwidth to 20 MHz Push the More lower bezel button repeatedly to select Offset Check that the vertical position is set to 0 divs If not turn the Vertical Position knob to set the position to 0 or push the appropriate Set to 0 divs button Push the front panel Acquire button Push the Mode lower bezel button and push the Average side bezel button The default number of averages is 16 Push the front panel Trigger Menu button Push the Source lower bezel button MSO4000 and DPO4000 Series Specifications and Performance Verification 2 27 Performance Verification Check Sample Rate and 2 28 Delay Time Accuracy 17 18 19 20 21 22 23 24 25 Turn the Multipurpose a knob to select the AC Line as the trigger source Push the front panel Wave Inspector Measure button Push the Add Measure
20. div settings listed in the test record Set the calibrator to 1 MQ output impedance to generate a sine wave Push the channel button 1 2 3 4 for the same channel that you used in step 3 Change the oscilloscope impedance to 1 MQ Push the Impedance lower bezel button to select 1 M Q Repeat steps 9 through 17 Repeat steps 3 through 21 for each channel combination listed in the test record and relevant to your model of oscilloscope for example 1 2 3 4 5 4000 and DPO4000 Series Specifications and Performance Verification Performance Verification Check DC Gain Accuracy This test checks the DC gain accuracy 1 Connect the oscilloscope to a DC voltage source If using the Wavetek 9500 calibrator connect the calibrator head to the oscilloscope channel to test Oscilloscope calibrator DE DC Voltage source Ch 1 2 Push the front panel Default Setup button to set the instrument to the factory gt enn A 10 11 12 13 14 15 16 default settings Push the channel button 1 2 3 4 for the channel that you want to check Confirm that the oscilloscope and calibrator impedances are both set to 50 Q Push the Impedance lower bezel button to select 50 Q Push the lower bezel Bandwidth button Push the 20 MHz side bezel button to select the bandwidth Push the front panel Acquire button Push the Mode lower bezel button and push the Average side bezel button T
21. ps 400 s 1 ns 400s 400 ps 1 000 s 1 ns 1 000 s 1 2 4 sequence 1 2 4 sequence except one position in each record length selection which is 0 8 2 4 Peak Detect or Envelope mode pulse response typical Sample rate range Record length range Maximum update rate Aperture Uncertainty typical Number of Waveforms for Average Acquisition Mode Table 1 4 Trigger specifications Characteristic Minimum pulse width DPO4104 MSO4104 gt 200 ps DPO4054 DPO4034 DPO4032 MSO4054 MS04034 MSO4032 gt 400 ps DPO4104 MS0O4104 5 GS s 0 1 S s DPO4054 DPO4034 DPO4032 MSO4054 MSO4034 MSO4032 2 5 GS s 0 1 S s 10 M 1 M 100 k 10 k 1 k Maximum triggered acquisition rate 50 000 wfm s 3 ps 0 1 ppm x record duration aus for records having duration 1 minute 2 to 512 waveforms Default of 16 waveforms Description Aux In External trigger maximum input voltage The maximum input voltage at the BNC between center conductor and shield is 400 Vpeak DF 39 2 250 Vous to 2 MHz derated to 5 Vous 500 MHz The maximum transient withstand voltage is 800 Mach Aux In External trigger input impedance typical 1 M Q 1 in parallel with 13 pF 2 pF Aux In External trigger bandwidth typical 250 MHz 20 Trigger bandwidth Edge Pulse and Logic typical DPO4104 MSO4104 1 GHz DPO4054 MSO4054 500 MHz DPO4034 DPO4032 MS04034 MS04032 350 MHz Time accuracy for Puls
22. shock the grounding conductor must be connected to earth ground Before making connections to the input or output terminals of the product ensure that the product is properly grounded Observe All Terminal Ratings To avoid fire or shock hazard observe all ratings and markings on the product Consult the product manual for further ratings information before making connections to the product The inputs are not rated for connection to mains or Category II III or IV circuits Connect the probe reference lead to earth ground only Do not apply a potential to any terminal including the common terminal that exceeds the maximum rating of that terminal Power Disconnect The power switch disconnects the product from the power source See instructions for the location Do not block the power switch it must remain accessible to the user at all times Do Not Operate Without Covers Do not operate this product with covers or panels removed Do Not Operate With Suspected Failures If you suspect that there is damage to this product have it inspected by qualified service personnel Avoid Exposed Circuitry Do not touch exposed connections and components when power is present Do Not Operate in Wet Damp Conditions Do Not Operate in an Explosive Atmosphere Keep Product Surfaces Clean and Dry Provide Proper Ventilation Refer to the manual s installation instructions for details on installing the product so it has proper ventilation
23. the Horizontal Acquire button and then 1f necessary press the bottom bezel Mode button to display the Acquisition Mode menu Press the side bezel Average button and if necessary use the multipurpose a knob to set the number of averages to 16 Press the front panel Wave Inspector Measure button and then if necessary press the bottom bezel More button to select Statistics and then press the side bezel Reset Statistics button Press the front panel Menu Off button to remove the menus from the display Read the RMS Mean value This is the Averaged Mean Value AMV MS04000 and DPO4000 Series Specifications and Performance Verification 13 14 15 16 17 18 19 20 21 22 1 Performance Verification Calculate the RMS noise RMS noise SMV AMV and enter the calculated RMS noise into the appropriate segment of the Test Record Set the Acquisition Mode to Sample a Press the front panel Horizontal Acquire button b If necessary press the bottom bezel Mode button to display the Acquisition Mode menu c Press the side bezel Sample button Set the input impedance to 50 Q a Press the front panel button for the channel being tested 1 2 3 or 4 b Press the bottom bezel Impedance button to select 50 O Press the front panel Wave Inspector Measure button and repeat steps 5 through 14 Set the channel under test to 1 MO impedance and set the bandwidth to 250 MHz a Press th
24. time width time between channels 1 Logic Not applicable 2 ns 1 ns Time Qualified 4 ns 2 ns 1 ns Logic Minimum clock pulse widths for setup hold time violation trigger typical For all vertical settings the minimums are Minimum pulse width clock active 2 Minimum pulse width clock inactive User hold time 2 5 ns 2 ns Setup hold violation trigger setup Feature Min Max and hold time ranges DPO4000 only Setup time 0 ns 8s Hold time 4 ns 8s Setup Hold time 4 ns 16s MSO4000 only Feature Min Max Setup time 0 5 ns 1 0 ms Hold time 1 ns 1 0 ms Setup Hold time 0 5 ns 2 0 ms Input coupling on clock and data channels must be the same For Setup time positive numbers mean a data transition before the clock For Hold time positive numbers mean a data transition after the clock edge Setup Hold time is the algebraic sum of the Setup Time and the Hold Time programmed by the user MSO4000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 4 Trigger specifications cont Characteristic Pulse type trigger minimum pulse rearm time minimum transition time Description Pulse class Minimum pulse Minimum rearm time width Glitch 4 ns 2 ns 5 of glitch width setting Runt 4 ns 2 ns Time qualified runt 4 ns 8 5 ns 5 of width setting Width 4ns 2 ns 5 of width upper limit setting Slew rate 4 ns 8 5 ns 5 of delta ti
25. 0 707 1 50 2 mVidiv 2 0 707 1 50 1 mV div 2 0 707 1 1 MO 5 mV div 2 0 707 1 1 MQ 2 mVidiv 2 0 707 1 1 MO 1 mV div 2 0 707 2 50 5 mV div 2 0 707 2 50 2 mVidiv 20 707 2 50 1 mV div 20 707 2 1 MO 5 mV div 20 707 2 1 MO 2 mVidiv 20 707 2 1 MQ 1 mV div 20 707 DPO4104 DPO4054 DPO4034 MSO4104 MSO4054 MS04034 3 50 5 mV div 2 0 707 3 50 2 mVidiv 20 707 3 50 1 mV div 20 707 3 1 MO 5 mV div 2 0 707 3 1 MO 2 mVidiv 2 0 707 3 1 MO 1 mV div 2 0 707 4 50 5 mV div 2 0 707 2 6 MSO4000 and DPO4000 Series Specifications and Performance Verification Performance Verification Performance checks Bandwidth Test result Bandwidth at Gain Channel Impedance Vertical scale Vin pp Vow pp Limit Vow pp Vin pp 4 500 2 mV div 20 707 4 500 1 mV div 20 707 4 1MQ 5 mV div 2 0 707 4 1 MQ 2 mV div 2 0 707 4 1 MQ 1 mV div 2 0 707 DC Gain Accuracy Performance checks Vertical scale Low limit Test result High limit All models Channel 1 DC Gain 1 mV div 1 5 1 5 E SE 2 mVidiv 1 5 1 5 20 MHz BW 50 Q 4 98 mV 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 0 V div 1 5 1 5 Channel 1 DC Gain 1 mV div 1 5 1 5 Accuracy 0 V offset 2 mvidiv 1 5 1 5 0 V vertical position 2
26. 0 MHz BW 1 MO 4 98 mV div 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 V div 1 5 1 5 5 4000 and DPO4000 Series Specifications and Performance Verification 2 7 Performance Verification DC Gain Accuracy Performance checks Vertical scale Low limit High limit Channel 2 DC Gain 1 mV div 1 5 1 5 eer 2 mVidiv 1 5 1 5 20 MHz BW 50 Q 4 98 mV 3 0 3 0 5 mVidiv 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 0 V div 1 5 1 5 Channel 2 DC Gain 1 mV div 1 5 1 5 Accuracy 0 V offset 2 mid 1 5 1 5 OMENIMO 498 mVidv 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 V div 1 5 1 5 DPO4104 DPO4054 DPO4034 MSO4104 MS04054 MSO4034 Channel 3 DC Gain 1 mVidiv 1 5 1 5 Accuracy 0 V offset 5 mvidiv 1 5 1 5 A 3 0 3 0 5 mV div 1 5 1 5 10 mV div 1 5 1 5 20 mV div 1 5 1 5 49 8 mV 3 0 3 0 50 mV div 1 5 1 5 100 mV div 1 5 1 5 200 mV div 1 5 1 5 500 mV div 1 5 1 5 1 0 V div
27. 0 mV Channel 3 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MO Full BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 4 DC Balance 1 mV div 0 5 mV 0 5 mV 50 Q 20 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 4 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MQ 20 MHz BW 100 mVidiv 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 4 DC Balance 1 mV div 0 5 mV 0 5 mV 50 Q 250 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV 5 4000 and DPO4000 Series Specifications and Performance Verification 2 5 Performance Verification DC Balance Performance checks Vertical scale Low limit Test result High limit Channel 4 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MQ 250 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 4 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q Full BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 4 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MO Full BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV 1 Immediately after calibration the specification is 0 2 div to 0 20 div For performance verification testing the specification is 0 3 to 0 3 div Performance checks Bandwidth Test result Bandwidth at Gain Channel Impedance Vertical scale Vin pp Vow pp Limit Vow pp Vin pp All models 1 50 0 5 mV div 2
28. 1 mV div 200 MHz 1 MO 5 mV div 380 MHz 1 MO 2 mVidiv 300 MHz 1 MO 1 mV div 175 MHz Model DPO4054 MSO4054 500 5 mVidiv 500 MHz 500 2 mVidiv 350 MHz 500 1 mVidiv 200 MHz 1 MO 5 mVidiv 380 MHz 1 MSO4000 and DPO4000 Series Specifications and Performance Verification 2 23 Performance Verification 2 24 Table 2 1 Maximum Bandwidth Frequency worksheet cont Model DPO4054 MSO4054 1 MO 2 mV div 300 MHz 1 MQ 1 mVidiv 175 MHz Model DPO4034 DPO4032 MSO4034 MS04032 500 5 mV div 350 MHz 500 2 mV div 350 MHz 500 1 mVidiv 200 MHz 1 MO 5 mV div 350 MHz 1 MO 2 mV div 300 MHz 1 MO 1 mVidiv 175 MHz 1 16 17 18 19 20 21 22 For DPO4104 MSO4104 DPO4054 and MSO4054 bandwidth verification use 380 MHz rather than 500 MHz on the 5 mV div vertical scale due to an impedance mismatch between the calibrator and the oscilloscope When the calibrator is set to 1 MO load it has a Thevenin equivalent 25 Q source impedance Passing the test with a 380 MHz signal verifies 500 MHz performance with a P6139A probe on models DPO4104 MSO4104 DPO4054 and MS0O4054 Use the values of Vsw pp andV obtained above and stored in the test record to calculate the Gain at bandwidth with the following equation Gain Ham Vin pp To pass the performance measurement test Gain should be gt 0 707 Enter Gain in the test record Repeat steps 9 through 16 for the other oscilloscope volts
29. 3 seconds and check the logic level of the corresponding digital channel in the display If the channel is at a static logic level high record the Vs value as in the 0 V row of the test record If the channel is a logic level low or is alternating between high and low repeat this step increment Vs by 10 mV wait 3 seconds and check for a static logic high until a value for V is found Push the Slope lower bezel button to change the slope to Falling Set the DC voltage source Vs to 400 mV Wait 3 seconds Check the logic level of the corresponding digital channel in the display If the channel 15 a static logic level low change the DC voltage source Vs to 500 mV Decrement Vs by 10 mV Wait 3 seconds and check the logic level of the corresponding digital channel in the display If the channel is at a static logic level low record the Vs value as V in the 0 V row of the test record If the channel is a logic level high or is alternating between high and low repeat this step decrement Vs by 10 mV wait 3 seconds and check for a static logic low until a value for V is found Find the average Vsavg Vs Vs 2 Record the average as the test result in the test record Compare the test result to the limits If the result is between the limits continue with the procedure to test the channel at the 4 V threshold value The remaining part of this procedure is for the 4 V threshold test Push the front panel D15 D0 b
30. 5 mV div 30 9 V 10 5 V 100 mV div to 500 mV div 10 V 10 V 505 mV div to 995 mV div 5 V 5 V 1 Vidiv to 5 V div 1 100 V 5 V 5 05 V div to 10 V div 1 50 V Not applicable Input Signal cannot exceed Max Input Voltage for the 50 Q input path Refer to the Max Input Voltage specification for more information 0 005 x offset position DC Balance Note Both the position and constant offset term must be converted to volts by multiplying by the appropriate volts div term MS04000 and DPO4000 Series Specifications and Performance Verification Table 1 1 Analog channel input and vertical specifications cont Specifications Characteristic Description Random Noise RMS Noise Son Acquisition Model Bandwidth selection 1 500 DPO4104 Full Bandwidth 133 uV 7 3 of 12 3 uV 6 of Volts div Setting Volts div Setting 250 MHz 99 5 uV 5 0 of 99 5 uV 5 0 of Volts div Setting Volts div Setting 20 MHz 20 8 uV 3 3 of 12 8 uV 3 3 of Volts div Setting Volts div Setting DPO4054 Full Bandwidth 130 uV 7 6 of S 77 9 uV 3 1 of Volts div Setting Volts div Setting 250 MHz 96 2 uV 5 2 of 56 7 UV 3 3 of Volts div Setting Volts div Setting 20 MHz 22 7 uV 3 8 of 13 6 uV 3 3 of Volts div Setting Volts div Setting DPO4034 Full Bandwidth 139 uV 6 4 of lt 77 7 UV 3 3 of Volts div Setting Volts div Setting 250 MHz 94 0
31. 90 mV 49 8 mV 448 2 mV 224 1 mV 224 1 mV 50 mV 450 mV 225 mV 225 mV 100 mV 900 mV 450 mV 450 mV 200 mV 1800 mV 900 mV 900 mV 500 mV 4900 mV 2450 mV 2450 mV 1 0 V 9000 mV 4500 mV 4500 mV 18 Calculate Vayas follows Vai Vregative measured E V positive measured Enter Vii as shown in the table See Table 2 2 19 Calculate GainAccuracy as follows GainAccuracy Vai V aigexpected y V diffExpected gt 100 Write down GainAccuracy in a table and in the test record See Table 2 2 20 Repeat steps 15 through 19 for each volts division value in the test record 21 Change the oscilloscope impedance to 1 MQ and repeat steps 15 through 20 22 Repeat steps 3 through 21 for each channel of the oscilloscope that you want to check 2 26 MS04000 and DPO4000 Series Specifications and Performance Verification Performance Verification Check Offset Accuracy This test checks the offset accuracy 1 Connect the oscilloscope to a DC voltage source to run this test If using the Wavetek calibrator as the DC voltage source connect the calibrator head to the oscilloscope channel to test Oscilloscope calibrator Ge DC Voltage source Ch 1 2 Push the front panel Default Setup button to set the instrument to the factory 10 11 12 13 14 15 16 default settings Push the channel button 1 2 3 4 for the channel that you want to check Confirm that the oscilloscope and
32. MSO4000 and DPO4000 Series Digital Phosphor Oscilloscopes Specifications and Performance Verification Technical Reference Tektronix 077 0247 00 S MSO4000 and DPO4000 Series Digital Phosphor Oscilloscopes Specifications and Performance Verification Technical Reference This document supports firmware version 2 00 and above for both MSO4000 Series instruments and DPO4000 Series instruments Warning The servicing instructions are for use by qualified personnel only To avoid personal injury do not perform any servicing unless you are qualified to do so Refer to all safety summaries prior to performing service www tektronix com 077 0247 00 Tektronix 7 Copyright O Tektronix All rights reserved Licensed software products are owned by Tektronix or its subsidiaries or suppliers and are protected by national copyright laws and international treaty provisions Tektronix products are covered by U S and foreign patents issued and pending Information in this publication supersedes that in all previously published material Specifications and price change privileges reserved TEKTRONIX and TEK are registered trademarks of Tektronix Inc Tektronix is an authorized licensee of the CompactFlash trademark Contacting Tektronix Tektronix Inc 14200 SW Karl Braun Drive P O Box 500 Beaverton OR 97077 USA For product information sales service and technical support n North America call 1 800 833 9200
33. Series Specifications and Performance Verification Performance Verification 14 Repeat steps 11 through 13 for each setting combination shown in the Test Record for the channel being tested 15 Press the front panel channel button for the next channel to be tested and move the coaxial cable to the appropriate input on the oscilloscope 16 Repeat steps 5 through 15 until all channels have been tested Check Digital Threshold For the MSO4000 series only this test checks the threshold accuracy of the digital Accuracy MSO4000 only channels This procedure applies to digital channels DO through D15 and to channel threshold values of 0 V and 4 V 1 Connect the P6516 digital probe to the MSO4000 series instrument Oscilloscope calibrator DMM and DC Voltage source Oscilloscope ecc Ef VL SES e 9 0 ole O c p eoooq BNC to 0 1 inch II pin adapter P6516 probe 2 Connect one of the digital channels such as DO to the DC voltage source to run this test If using the Wavetek calibrator as the DC voltage source connect the calibrator head to the digital channel to test You will need a BNC to 0 1 inch pin adapter to complete the connection Be sure to connect the digital channel to the corresponding signal pin and to a ground pin on the adapter 3 Push the front panel Default Setup button to set the instrument to t
34. al source to the oscilloscope channel being tested Oscilloscope calibrator Oscilloscope Leveled Sine wave generator Press the channel 1 button to display the channel 1 menu Press the bottom bezel Impedance button to set the channel to 50 O Press the front panel Trigger Menu button and then if necessary set the trigger source to the channel being tested a Press the bottom bezel Source button b Use the Multipurpose a knob to select the channel being tested Press the Wave Inspector Measure button and then press the bottom bezel Add Measurement button Use the Multipurpose a knob to select the Burst Width measurement and then press the side bezel OK Add Measurement button Press the bottom bezel More button to select Statistics and 1f necessary use the mutipurpose a knob to set the Mean amp Std Dev Samples to 100 as shown in the side menu Press the front panel Menu Off button to remove the Statistics menu Refer to the Test Record Delta Time Measurement Accuracy table Set the oscilloscope and the signal source as directed there Press the bottom bezel More button to select Statistics and the press the side bezel Reset Statistics button and wait five or 10 seconds for the oscilloscope to acquired all the samples before taking the reading Verify that the Std Dev is less than the upper limit shown for each setting and note the reading in the Test Record 5 4000 and DPO4000
35. aving rise and fall times 210 ns the limits are as follows Source Range Any channel 30 20 divisions Aux In external trigger 10 of setting 25 mV Line Not applicable Trigger holdoff range 20 ns minimum to 8 s maximum Video type trigger sensitivity typical The limits for both delayed and main trigger are as follows Source Sensitivity Any input channel 0 6 to 2 5 divisions of video sync tip Aux In External Video not supported through Aux In External input Video type trigger formats and field rates Triggers from negative sync composite video field 1 or field 2 for interlaced systems on any field specific line or any line for interlaced or non interlaced systems Supported systems include NTSC PAL and SECAM MS04000 and DPO4000 Series Specifications and Performance Verification Table 1 4 Trigger specifications cont Characteristic Description Specifications Logic type or logic qualified trigger or events delay sensitivities DC coupled typical 1 0 division from DC to maximum bandwidth Pulse type runt trigger sensitivities typical 1 0 division from DC to maximum bandwidth Pulse type trigger width and glitch sensitivities typical 1 0 division Logic type triggering minimum logic or rearm time typical For all vertical settings the minimums are Trigger type Minimum pulse Minimum re arm Minimum
36. by 10 mV Wait 3 seconds and check the logic level of the corresponding digital channel in the display If the channel is at a static logic level high record the Vs value as in the 4 V row of the test record If the channel is a logic level low or is alternating between high and low repeat this step increment Vs by 10 mV wait 3 seconds and check for a static logic high until a value for V is found Find the average Vsave V Vs 2 Record the average as the test result in the test record Compare the test result to the limits If the result is between the limits the channel passes the test Repeat the procedure starting with step 11 for each remaining digital channel D1 through D15 This completes the performance verification procedure 5 4000 and DPO4000 Series Specifications and Performance Verification 2 35
37. c state derived from more than one channel must exist to be recognized For events the time is the minimum time between a main and delayed event that will be recognized if more than one channel is used An active pulse width is the width of the clock pulse from its active edge as defined through the Define Inputs lower bezel button and the Clock Edge side bezel menu to its inactive edge An inactive pulse width is the width of the pulse from its inactive edge to its active edge The User hold time is the number selected by the user through the Times lower bezel button and the Hold Time side bezel menu DPO4000 Series S N CO20000 B020000 and above MSO4000 Series all units MS04000 and DPO4000 Series Specifications and Performance Verification Table 1 5 Display specifications Characteristic Specifications Description Display type Display area 210 4 mm 8 28 inches H x 157 8 mm 6 21 inches V 264 mm 10 4 inches diagonal 6 bit RGB full color XGA 1024 x 768 TFT liquid crystal display LCD Display resolution 1000 horizontal by 651 vertical displayed pixels Luminance typical Minimum 240 cd m typical 300 cd m Waveform display color scale The TFT display can support up to 262 144 colors A subset of these colors are used for the oscilloscope display all of which are fixed colors and not changeable by the customer Table 1 6 Input Output port specifications Characteristic Description
38. dures verify the performance of your instrument They do not adjust your instrument If your instrument fails any of the performance verification tests you should perform the factory adjustment procedures as described in the Tektronix 4000 Series Service Manual MSO4000 and DPO4000 Series Specifications and Performance Verification 2 1 Performance Verification Upgrade the Firmware For the best functionality you can upgrade the oscilloscope firmware To upgrade the firmware follow these steps 1 Open up a Web browser and go to www tektronix com software Use the Software and Firmware Finder to locate the most recent firmware upgrade Download the latest firmware for your oscilloscope onto your PC Unzip the files and copy the firmware img file into the root folder of a USB flash drive Power off your oscilloscope Insert the USB flash drive into a USB Host port on the front or back of the oscilloscope Power on the oscilloscope The oscilloscope automatically recognizes the replacement firmware and installs it If the instrument does not install the firmware rerun the procedure If the problem continues contact qualified service personnel NOTE Do not power off the oscilloscope or remove the USB flash drive until the oscilloscope finishes installing the firmware 10 11 12 13 2 2 The oscilloscope displays a message when the installation is complete Power off the oscilloscope and remove the USB f
39. e Glitch Timeout or Width triggering Time range Accuracy 1 ns to 500 ns 20 of setting 0 5 ns 520 ns to1s 0 01 of setting 100 ns MSO4000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 4 Trigger specifications cont Characteristic Description Edge type trigger sensitivity DC coupled typical Trigger Source Sensitivity Any input channel 0 40 div from DC to 50 MHz increasing to 1 div at oscilloscope bandwidth Aux in External 200 mV from DC to 50 MHz increasing to 500 mV at 250 MHz Line Fixed Edge trigger sensitivity not DC Trigger Coupling Typical Sensitivity coupled typical NOISE REJ 2 5 times the DC coupled limits HF REJ 1 5 times the DC coupled limit from DC to 50 kHz Attenuates signals above 50 kHz LF REJ 1 5 times the DC coupled limits for frequencies above 50 kHz Attenuates signals below 50 kHz Trigger level ranges Source Sensitivity Any input channel 8 divisions from center of screen 8 divisions from 0 V when vertical LF reject trigger coupling is selected Aux In External 8 V Line Not applicable The line trigger level is fixed at about 50 of the line voltage This specification applies to logic and pulse thresholds Lowest frequency for successful operation of Set Level to 50 function typical 45 Hz Trigger level accuracy DC coupled typical For signals h
40. e testing as shown in the test record for example 1 2 3 4 Set the oscilloscope impedance to 50 Q Push the Impedance lower bezel button to select 50 Q Push the lower bezel Bandwidth button and push the appropriate bandwidth side bezel button for 20M Hz 250MHz or Full as given in the test record Turn the Horizontal Scale knob to 1 ms division Turn the Vertical Scale knob to set the vertical scale as shown in the test record for example 1 mV div 2 mV div 100 mV div 1 V div Push the front panel Acquire button Push the Mode lower bezel button and then if needed push the Average side bezel button If needed adjust the number of averages to 16 with the Multipurpose a knob Push the Trigger Menu front panel button Push the Source lower bezel button Select the AC Line trigger source with the Multipurpose a knob You do not need to connect an external signal to the oscilloscope for this DC Balance test Push the front panel Wave Inspector Measure button Push the Add Measurement lower bezel button Use the Multipurpose a knob to select the Mean measurement MSO4000 and DPO4000 Series Specifications and Performance Verification 2 21 Performance Verification 2 22 Check Bandwidth 17 18 19 20 21 22 Push the OK Add Measurement side bezel button View the mean measurement value in the display and enter that mean value as the test result in the test record Repeat steps 7 through 18 fo
41. e front panel button for the channel being tested 1 2 3 or 4 b Press the bottom bezel Impedance button to select 1 MQ c Press the bottom bezel Bandwidth button and then press the side bezel 250M Hz button Press the front panel Waveform Inspector Measure button and then repeat steps 5 through 16 Set the channel under test to 1 MO impedance and set the bandwidth to 20 MHz a Press the front panel button for the channel being tested 1 2 3 or 4 b Press the bottom bezel Impedance button to select 1 MQ c Press the bottom bezel Bandwidth button and then press the side bezel 20MHz button Press the front panel Wave Inspector Measure button and then repeat steps 5 through 16 Select the next channel 2 3 or 4 to test and then press the front panel Wave Inspector Measure button Repeat steps 5 through 21 until all channels have been tested Channels 3 and 4 are only on four channel oscilloscopes MS04000 and DPO4000 Series Specifications and Performance Verification 2 31 Performance Verification Check Delta Time Measurement Accuracy This test checks the Delta time measurement accuracy DTA for a given instrument setting and input signal 1 2 10 1 12 13 Set the sine wave generator output impedance to 50 Press the oscilloscope front panel Default Setup button and then press the Menu Off button to remove the side bezel menu Connect a 50 Q coaxial cable from the sign
42. ent Any sample DC gain accuracy 2 reading offset position Offset Accuracy 0 15 div 0 6 mV ee d Delta volts between any two samples acquired DC gain accuracy 2 reading 0 15 div Hid EIERE with the same oscilloscope setup and ambient 1 2 mV typica conditions Average acquisition mode Note Offset position and the constant offset term must be converted to volts by multiplying by the appropriate volts div term Average of 2 16 waveforms DC gain accuracy 2 reading offset position Offset Accuracy 0 1 div Delta Volts between any two averages of 216 DC gain accuracy 2 reading 0 05 div waveforms acquired with the same oscilloscope setup and ambient conditions Note Offset position and the constant offset term must be converted to volts by multiplying by the appropriate volts div term The basic accuracy specification applies directly to any sample and to the following measurements High Low Max Min Mean Cycle Mean RMS and Cycle RMS The delta volt accuracy specification applies to subtractive calculations involving two of these measurements The delta volts difference voltage accuracy specification applies directly to the following measurements Positive Overshoot Negative Overshoot Pk Pk and Amplitude Offset ranges Offset accuracy Volts div setting Offset range 1 MQ input 50 input 1 mV div to 50 mV div 1V 50 5 mV div to 99
43. he default number of averages is 16 Push the front panel Wave Inspector Measure button and the Add Measurement lower bezel button Use the Multipurpose a knob to select the Mean measurement Push the OK Add Measurement side bezel button Push the Trigger Menu front panel button Push the Source lower bezel button Turn the Multipurpose a knob to select the AC Line as the trigger source Turn the vertical Scale knob to the next setting to measure as shown in the table See Table 2 2 Set the DC Voltage Source to V negative See Table 2 2 Push the Measure front panel button push the Statistics lower bezel button and push Reset Statistics in the side bezel menu Enter the mean reading in a table as V negative measured See Table 2 2 MSO4000 and DPO4000 Series Specifications and Performance Verification 2 25 Performance Verification 17 Set the DC Voltage Source to Vs See Table 2 2 Push Statistics in the lower bezel menu and Reset Statistics in the side bezel menu Enter the mean reading in the following table as Vpositive measured Table 2 2 Gain Expected worksheet Test Oscilloscope Result Vertical Scale Gain Setting Vaittexpected V negative V positive Vnegative measured Vpositive measured Van Accuracy 1 mV div 9 mV 4 5 mV 4 5 mV 2 mVidiv 18 mV 9 mV 9 mV 4 98 mV 44 82 mV 22 41 mV 22 41 mV 5 mV 45 mV 22 5 mV 22 5 mV 10 mV 90 mV 45 mV 45 mV 20 mV 180 mV 90 mV
44. he factory default settings 4 Push the front panel D15 D0 button 5 Push the D15 D0 On Off lower bezel button 6 Push the Turn On D7 DO and the Turn On D15 D8 side bezel buttons The instrument will display the 16 digital channels 7 Push the Thresholds lower bezel button 8 Turn the Multipurpose a knob and select the D15 DO group 5 4000 and DPO4000 Series Specifications and Performance Verification 2 33 Performance Verification 10 11 12 13 14 15 16 17 18 Before you change the threshold value push the Fine front panel button to turn off the fine adjustment and make adjusting the value quicker Turn the Multipurpose b knob and set the value to 0 00 V 0 V div The thresholds are set for the 0 V threshold check You need to record the test values in the row for 0 V in the test record for each digital channel Push the front panel Trigger Menu button Push the Source lower bezel button and turn Multipurpose a knob to select the appropriate channel such as DO By default the Type is set to Edge Coupling is set to DC Slope is set to Rising Mode is set to Auto and Level is set to match the threshold of the channel being tested Set the DC voltage source Vs to 400 mV Wait 3 seconds Check the logic level of the corresponding digital channel in the display If the channel is a static logic level high change the DC voltage source Vs to 500 mV Increment Vs by 10 mV Wait
45. ical shock always set voltage source outputs to 0 V before making or changing any interconnections Self Test This procedure uses internal routines to verify that the oscilloscope functions and passes its internal self tests No test equipment or hookups are required Start the self test with these steps 1 2 Disconnect all probes and cables from the oscilloscope inputs Push the front panel Default Setup button to set the instrument to the factory default settings Push the Utility menu button Push the Utility Page lower bezel button and turn the Multipurpose a knob to select Self Test Push the Self Test lower bezel button The Loop X Times side bezel menu will be set to Loop 1 Times Push the OK Run Self Test side bezel button Wait while the self test runs When the self test completes a dialog box displays the results of the self test Push the Menu Off button to clear the dialog box and Self Test menu MSO4000 and DPO4000 Series Specifications and Performance Verification 2 19 Performance Verification Check Input Impedance This test checks the Input Impedance Resistance 1 Connect the output of the oscilloscope calibrator for example Fluke 9500 to the oscilloscope channel 1 input as shown below Oscilloscope Oscilloscope calibrator 5 5 5 Ch 1 2 Push the front panel Default Setup button to set the instrument to the factory default se
46. ies Specifications and Performance Verification Performance Verification Performance Verification This chapter contains performance verification procedures for the specifications marked with the symbol The following equipment or a suitable equivalent is required to complete these procedures Description Minimum requirements Examples DC voltage source 3 mV to 4 V 0 1 accuracy Fluke 9500 Oscilloscope Calibrator with a Leveled sine wave generator 50 kHz to 1000 MHz 4 amplitude 9510 Output Module accuracy An appropriate BNC to 0 1 inch pin Time mark generator 80 ms period 1 ppm accuracy rise time adapter between the Fluke 9500 and P6516 probe 50 ns Digital Multimeter DMM 0 1 accuracy or better One 50 BNC cable Male to male connectors Tektronix part number 012 0057 01 You may need additional cables and adapters depending on the actual test equipment you use These procedures cover all DPO4000 and MSO4000 models Please disregard checks that do not apply to the specific model you are testing Print the test record on the following pages and use it to record the performance test results for your oscilloscope NOTE Completion of the performance verification procedure does not update the stored time and date of the latest successful adjustment The date and time are updated only when the adjustment procedures in the service manual are successfully completed The performance verification proce
47. imum input voltage at the BNC between the center conductor and shield is 400 Vpeak DF lt 39 2 250 Vous to 130 kHz derated to 2 6 Vous at 500 MHz The maximum transient withstand voltage is 800 Vpeak DC Balance 0 2 div with the input DC 50 coupled and 50 terminated 0 25 div at 2 mV div with the input DC 50 O coupled and 50 terminated 0 5 div at 1 mV div with the input DC 50 coupled and 50 terminated 0 2 div with the input DC 1 MO coupled and 50 O terminated 0 3 div at 1 mV div with the input DC 1 MO coupled and 50 O terminated MSO4000 and DPO4000 Series Specifications and Performance Verification 1 1 Specifications Table 1 1 Analog channel input and vertical specifications cont Characteristic Description Delay between 100 ps between any two channels with input impedance set to 50 Q DC coupling channels full bandwidth typical Note all settings in the instrument can be manually time aligned using the Probe Deskew function from 100 ns to 100 ns with a resolution of 20 ps Deskew range 100 ns to 100 ns with a resolution of 20 ps Crosstalk channel isolation typical 2100 1 at 100 MHz and 230 1 at 2100 MHz up to the rated bandwidth for any two channels having equal Volts Div settings TekVPI Interface The probe interface allows installing powering compensating and controlling a wide range of probes offering a variety of features The interface is available on
48. k A programmable clock providing time in years months days hours minutes and seconds Compact Flash card Used to store reference waveforms and front panel settings Supply Voltage Form factor Data bits Switched 3 3 V only Type 1 only 16 bit data transfer Table 1 9 Environmental specifications Characteristic Description Temperature Operating 0 C to 50 C 32 F to 122 F Nonoperating 20 C to 60 C 4 F to 140 F Humidity Operating High 10 to 60 relative humidity 40 C to 50 C 104 F to 122 F Low 10 to 90 relative humidity 0 C to 40 C 32 F to 104 F Nonoperating High 5 to 60 relative humidity 40 C to 60 C 104 F to 140 F Low 5 to 90 relative humidity 0 C to 40 C 32 F to 104 F Altitude Operating 3 000 m 9 843 ft Nonoperating 12 000 m 39 370 ft Pollution Degree Pollution Degree 2 indoor use only Random vibration Operating 0 31 gaus from 5 Hz to 500 Hz 10 minutes on each axis 3 axes Nonoperating 2 46 grus from 5 Hz to 500 Hz 10 minutes on each axis 3 axes 30 minutes total 1 14 MS04000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 10 Mechanical specifications Characteristic Description Dimensions Nominal non rack mount Height 229 mm 9 0 in including feet 272 mm 10 7 in including vertical handle and feet Width 439 mm 17 3 in from handle hub to handle hub
49. l 2 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 250 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 2 DC Balance 1 mV div 1 0 3 mV 0 3 mV 1 MQ 250 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 2 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q Full BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV 2 4 MSO4000 and DPO4000 Series Specifications and Performance Verification Performance Verification DC Balance Performance checks Vertical scale Low limit Test result High limit Channel 2 DC Balance 1 mV div 1 0 3 mV 0 3 mV 1 MO Full BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV DPO4104 DPO4054 DPO4034 MSO4104 MSO4054 MSO4034 Channel 3 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 20 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 3 DC Balance 1 mV div 1 0 3 mV 0 3 mV 1 MQ 20 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 3 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 250 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 3 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MQ 250 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 3 DC Balance 1 mV div 0 5 mV 0 5 mV 50 Q Full BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 20
50. lash drive Power on the oscilloscope Push the Utility front panel button Push the Utility Page lower bezel button Turn multipurpose knob a and select Config Push the About lower bezel button The oscilloscope displays the firmware version number Confirm that the version number matches that of the new firmware 5 4000 and DPO4000 Series Specifications and Performance Verification Test Record Model Serial Procedure performed by Performance Verification Date Test Passed Failed Self Test Input Impedance Performance checks Vertical scale Low limit Test result High limit All models Channel 1 Input 10 mV div 990 1 01 MQ Impedance 1 100 mVidiv 990 kQ 1 01 MO 1 Vidiv 990 1 01 MQ Channel 1 Input 10 mV div 49 5 Q 50 5 0 Impedance 50 Q 100 mV div 49 5 Q 50 5 0 Channel 2 Input 10 mV div 990 kQ 1 01 MQ Impedance 1 MQ 100 mV div 990 kQ 1 01 MO 1 Vidiv 990 1 01 MQ Channel 2 Input 10 mV div 49 5 Q 50 5 0 Impedance 50 Q 100 mV div 49 5 Q 50 5 0 DPO4104 DPO4054 DPO4034 MSO4104 MSO4054 MSO4034 Channel 3 Input 10 mV div 990 kQ 1 01 MQ Impedance 1 100 mV div 990 kQ 1 01 MO 1 Vidiv 990 1 01 MQ Channel 3 Input 10 mV div 49 5 Q 50 5 0 Impedance 50 Q 100 mV div 49 5 Q 50 5 0 Channel 4 Input 10 mV div 990 kQ 1 01 MQ Impedance 1 MQ 100 mVidiv 990 kQ 1 01 MQ 1 Vidiv 990 1 01 MQ Channel 4 I
51. me setting For the trigger class width and the trigger class runt the pulse width refers to the width of the pulse being measured The rearm time refers to the time between pulses For the trigger class slew rate the pulse width refers to the delta time being measured The rearm time refers to the time it takes the signal to cross the two trigger thresholds again Transition time trigger delta time range 4 ns to8s Time range for glitch pulse width timeout time qualified runt or time qualified window triggering 4ns to8s B trigger after events minimum pulse width and maximum event frequency typical 4 ns 500 MHz B trigger minimum time between arm and trigger typical 4ns For trigger after time this is the time between the end of the time period and the B trigger event For trigger after events this is the time between the last A trigger event and the first B trigger event B trigger after time time range 4ns to 8 seconds B trigger after events event range Maximum serial trigger bits 1 to 9 999 999 128 bits Standard Parallel bus interface triggering MSO4000 only Data user Trigger 1 to 20 bits of user specified data on 4 channel models and 1 to 18 bits of specified data on 2 channel models MS04000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 4 Trigger specifications cont Characteristic Description
52. ment lower bezel button Use the Multipurpose a knob to select the Mean measurement Push the OK Add Measurement side bezel button The mean value should appear in a measurement pane at the bottom of the display Enter the measured value in the test record Repeat the procedure for each volts division setting shown in the test record Change the impedance to 1 MQ and repeat steps 5 through 23 Repeat steps 3 through 24 for each channel of the oscilloscope that you want to check This test checks the sample rate and delay time accuracy time base 1 Oscilloscope calibrator Connect the output of the time mark generator to the oscilloscope channel 1 input using a 50 cable Oscilloscope Time mark generator 6 Set the time mark generator period to 80 ms Use a time mark waveform with a fast rising edge Push the front panel Default Setup button to set the instrument to the factory default settings Push the channel 1 button Set the impedance to 50 O Push the Impedance lower bezel button to select 50 Q If adjustable set the time mark amplitude to approximately 1 Vp p Set the Vertical SCALE to 500 mV div Set the Horizontal SCALE to 20 ms div MS04000 and DPO4000 Series Specifications and Performance Verification Performance Verification 9 Adjustthe Vertical POSITION knob to center the time mark signal on the screen 10 Adjust the Trigger LEVEL knob as necessary for
53. ndwidth selection set to FULL Reduce the upper bandwidth frequency by 1 for each C above 30 C Instrument 5 mV div to 1 V div 2 mV div to 1 mV div to 4 98 mV div 1 99 mV div DPO4104 MSO4104 DC to 1 GHz DC to 350 MHz DC to 200 MHz DPO4054 MSO4054 DC to 500 MHz DC to 350 MHz DC to 200 MHz Instrument 2 mV div to 1 V div 1 mV div to 1 99 V div DPO4034 MSO4034 DC to 350 MHz DC to 200 MHz DPO4032 MS04032 DC to 350 MHz DC to 200 MHz MS04000 and DPO4000 Series Specifications and Performance Verification Table 1 1 Analog channel input and vertical specifications cont Characteristic Description Specifications Analog bandwidth 1 MQ with P6139A 10X Probe typical The limits stated below are for ambient temperature of lt 30 C and the bandwidth selection set to FULL Reduce the upper bandwidth frequency by 1 for each C above 30 C Instrument 50 mV div to 100 V div 20 mV div to 10 mV div to 49 8 mV div 19 9 mV div DPO4104 MSO4104 DC to 500 MHz DC to 300 MHz DC to 175 MHz DPO4054 MS04054 DC to 500 MHz DC to 300 MHz DC to 175 MHz DPO4034 MS04034 DC to 350 MHz DC to 300 MHz DC to 175 MHz DPO4032 MS04032 DC to 350 MHz DC to 300 MHz DC to 175 MHz Calculated rise time The formula is calculated by measuring 3 dB bandwidth of the oscilloscope The formula accounts for the typical rise time contribution of the oscilloscope independent of the ri
54. nput 10 mV div 49 5 Q 50 5 Q Impedance 50 Q 100 mV div 4950 50 5 0 DC Balance Performance checks Vertical scale Low limit Test result High limit All models Channel 1 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 20 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV MSO4000 and DPO4000 Series Specifications and Performance Verification 2 3 Performance Verification DC Balance Performance checks Vertical scale Low limit Test result High limit Channel 1 DC Balance 1 mV div 1 0 3 mV 0 3 mV 1 MQ 20 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 1 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 250 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 1 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MQ 250 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 1 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q Full BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 1 DC Balance 1 mV div 0 3 mV 0 3 mV 1 MO Full BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 2 DC Balance 1 mV div 0 5 mV 0 5 mV 90 Q 20 MHz BW 2 mVidiv 0 5 mV 0 5 mV 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channel 2 DC Balance 1 mV div 1 0 3 mV 0 3 mV 1 MO 20 MHz BW 100 mV div 20 mV 20 mV 1 Vidiv 200 mV 200 mV Channe
55. onditions must first be met The oscilloscope must have been operating continuously for twenty minutes within the operating temperature range specified B You must perform the Signal Path Compensation SPC operation described in the Tektronix 4000 Series Digital Phosphor Oscilloscopes User Manual prior to evaluating specifications If the operating temperature changes by more than 10 C 18 F you must perform the SPC operation again Table 1 1 Analog channel input and vertical specifications Characteristic Description Number of input channels DPO4032 MSO4032 DPO4104 DPO4054 DPO4034 MSO4104 MSO4054 MSO4034 2 analog digitized simultaneously 4 analog digitized simultaneously Input coupling DC AC or GND GND coupling approximates ground reference by measuring the CVR output set to GND The signal being measured on the BNC is not disconnected from the channel s input load Input resistance selection 1 MO or 50 0 DPO4104 MSO4104 Bandwidth is limited to 500 MHz with 1 MO impedance selected V Input impedance DC coupled 1 MO 1 in parallel with 13 pF 2 pF 50 Q 1 DPO4104 MS04104 VSWR lt 1 5 1 from DC to 1 GHz typical DPO4054 MS04054 VSWR lt 1 5 1 from DC to 500 MHz typical DPO4034 DPO4032 MS04034 MS04032 VSWR 1 5 1 from DC to 350 MHz typical Maximum input voltage 50 Q 5 Vous With peaks lt 20 V DF lt 6 25 Maximum input voltage 1 MQ The max
56. or Maximum Data Rate 10 Mbps ps4 Data Trigger 32 bits of user specified data in a left word right word or either including qualifiers of equal to not equal to lt gt less than greater than gt less than or equal to lt greater than or equal to gt inside range outside range Trigger on Word Select Data Maximum Data Rate 12 5 Mbps Left Justified 4 Data Trigger 32 bits of user specified data in a left word right word or either including qualifiers of equal to not equal to lt gt less than greater than gt less than or equal to lt greater than or equal to gt inside range outside range Trigger on Word Select Data Maximum Data Rate 12 5 Mbps Right Justified 4 Data Trigger 32 bits of user specified data in a left word right word or either including qualifiers of equal to not equal to lt gt less than greater than gt less than or equal to lt greater than or equal to gt inside range outside range Trigger on Word Select Data Maximum Data Rate 12 5 Mbps 4 Data Trigger 32 bits of user specified data in a channel 0 7 including qualifiers of equal to not equal to lt gt less than lt greater than gt less than or equal to lt greater than or equal to gt inside range outside range Trigger on Frame Sync Data Maximum Data Rate 25 Mbps 1 For logic time between channels refers to the length of time a logi
57. r each volts division value listed in the results table Push the front panel channel button change the oscilloscope bandwidth for example 20 MHz 250 MHz or Full and repeat steps 5 through 19 Change the oscilloscope impedance to 1 MQ and repeat steps 5 through 20 Repeat steps 3 through 20 for each channel combination listed in the test record and relevant to your model of oscilloscope for example 1 2 3 or 4 This test checks the bandwidth at 50 Q and 1 M for each channel 1 Connect the output of the leveled sine wave generator for example Wavetek 9500 to the oscilloscope channel 1 input as shown below Oscilloscope calibrator Oscilloscope Leveled Sine wave generator Push the front panel Default Setup button to set the instrument to the factory default settings Push the channel button 1 2 3 4 for the channel that you want to check Set the calibrator to 50 Q output impedance 50 Q source impedance and to generate a sine wave Set the oscilloscope impedance to 50 Q Push the Impedance lower bezel button to select 50 0 Turn the Vertical Scale knob to set the vertical scale as shown in the test record for example 1 mV div 2 mV div 5 mV div Push the front panel Acquire button Confirm that the mode is set to Sample If not push the Mode lower bezel button and then push the Sample side bezel button Adjust the signal source to at least 8 vertical divisions
58. s Div Source freq 24 kHz 1mV 8 mV 940 ns 5 mV 40 mV 530 ns 100 mV 800 mV 430 ns 500 mV 4V 430 ns 1V 4V 850 ns MSO DPO 400 us Div Source freq 2 4 kHz 1mV 8 mV 9 4 us 5 mV 40 mV 5 3 us 100 mV 800 mV 4 3 us 500 mV 4 4 3 us 1V 4 8 5 us MSO4000 and DPO4000 Series Specifications and Performance Verification 2 15 Performance Verification Delta Time Measurement Accuracy Channel 31 MSO DPO 4 ns Div Source freq 240 MHz MSO DPO V Div Source Nu Test result High limit 5 mV 40 mV 55 ps 100 mV 800 mV 46 ps 500 mV 4V 45 ps 1V 4V 86 ps MSO DPO 40 ns Div Source freq 24 MHz 1mV 8 mV 940 ps 5mV 40 mV 530 ps 100 mV 800 mV 430 ps 500 mV 4V 430 ps 1V 4V 850 ps MSO DPO 400 ns Div Source freq 2 4 MHz 1mV 8 mV 9 4 ns 5 mV 40 mV 5 3 ns 100 mV 800 mV 4 3 ns 500 mV 4V 4 3 ns 1V 4V 8 5 ns MSO DPO 4 us Div Source freq 240 kHz 1mV 8 mV 94 ns 5mV 40 mV 53 ns 100 mV 800 mV 43 ns 500 mV 4V 43 ns 1V 4V 85 ns MSO DPO 40 us Div Source freq 24 kHz 1mV 8 mV 940 ns 5 mV 40 mV 530 ns 100 mV 800 mV 430 ns 500 mV 4V 430 ns 1V 4V 850 ns MSO DPO 400 us Div Source freq 2 4 kHz 1mV 8 mV 9 4 us 5mV 40 mV 5 3 us 100 mV 800 mV 4 3 us 500 mV 4V 4 3 us 1V 4V 8 5 us 2 16 MS04000 and DPO4000 Series Specifications and Performance Verification Performance Verification Delta Time Measurement Accuracy Channel 41 MSO DPO 4 ns Div Source freq 240 MHz MSO DPO V Div Source No Test result High limit 5 mV 40 mV
59. se time of the signal source Instrument 50 Q 1 mV div to 50 Q 2 mV div to 50 Q 5 mV div to 1 99 mV div 4 99 mV div 1 V div DPO4104 MSO4104 1 75 ns 778 ps 350 ps DPO4054 MSO4054 1 75 ns 778 ps 700 ps DPO4034 MSO4034 1 75 ns 1 ns 1 ns DPO4032 MSO4032 1 75 ns 1 ns 1 ns Instrument 1 MO P6139A 1 MQ P6139A probe 20 mV div to 100 V div probe 10 mV div to 19 9 mV div DPO4104 MSO4104 1 ns 700 ps DPO4054 MSO4054 1 ns 700 ps DPO4034 MSO4034 1 ns 1 ns DPO4032 MS04032 1 ns 1 ns Analog bandwidth selections 20 MHz 250 MHz and Full all models Lower frequency limit AC coupled typical 10 Hz when AC to 1 MO coupled The AC coupled lower frequency limits are reduced by a factor of 10 when 10X passive probes are used 250 MHz 20 all models Upper frequency limit 250 MHz bandwidth limited typical Upper frequency limit 20 MHz bandwidth limited typical 20 MHz 20 all models For 1 MQ path 31 900 derated at 0 100 C above 30 C 1 5 derated at 0 050 C above 30 C 3 0 Variable Gain derated at 0 100 C above 3 0 Variable Gain derated at 0 050 C above 30 C 30 C DC gain accuracy For 50 Q path 5 4000 and DPO4000 Series Specifications and Performance Verification 1 3 Specifications Table 1 1 Analog channel input and vertical specifications cont Characteristic Description DC voltage Measurement type DC Accuracy in volts measurem
60. ttings 3 Push the front panel channel button for the oscilloscope channel that you are testing as shown in the test record for example 1 2 3 4 4 Confirm that the oscilloscope and calibrator impedances are both set to 1 MQ The default Impedance setting is 1 MQ 5 Turn the Vertical Scale knob to set the vertical scale as shown in the test record for example 10 mV div 100 mV div 1 V div 6 Measure the input resistance of the oscilloscope with the calibrator Record this value in the test record 7 Repeat steps 5 and 6 for each volt division setting in the test record 8 Change the oscilloscope and calibrator impedance to 50 and repeat steps 5 through 7 9 Repeat steps 4 through 8 for each channel listed in the test record and relevant to the model of oscilloscope that you are testing as shown in the test record for example 2 3 or 4 2 20 5 4000 and DPO4000 Series Specifications and Performance Verification Performance Verification Check DC Balance This test checks the DC balance You do not need to connect the oscilloscope to any equipment to run this test Oscilloscope LI 2 ol fo 10 11 12 13 14 15 16 Attach a 50 terminator to the channel input of the oscilloscope being tested Push the front panel Default Setup button to set the instrument to the factory default settings Push the front panel channel button for the oscilloscope channel that you ar
61. uV 4 8 of 76 6 uV 3 2 of Volts div Setting Volts div Setting 20 MHz 22 3 uV 3 4 of 16 0 uV 3 1 of Volts div Setting Volts div Setting DPO4032 Full Bandwidth 141 uV 7 2 of 81 6 uV 3 1 of Volts div Setting Volts div Setting 250 MHz 87 9 uV 4 9 of 13 8 uV 3 9 of Volts div Setting Volts div Setting 20 MHz 18 5 uV 3 1 of 12 7 uV 3 6 of Volts div Setting Volts div Setting Aperture uncertainty lt 3 ps 0 1 ppm x Record Duration gus for records having duration 1 minute MSO4000 and DPO4000 Series Specifications and Performance Verification Specifications Table 1 1 Analog channel input and vertical specifications cont Characteristic Description Delta Time The formula to calculate delta time measurement accuracy DTA for a given instrument setting and input Measurement signal is given below assumes insignificant signal content above Nyquist Accuracy SR Slew Rate 1s Edge around 1st point in measurement SR Slew Rate 2 4 Edge around 2 4 point in measurement N input referred noise VoltSims Refer to Random Noise Sample Acquisition Mode TBA timebase accuracy 5 ppm Refer to Long term sample rate and delay time accuracy treading delta time measurement duration sec RecordDuration Record Length Sample Rate DT App N N 2 0 25 Xtsamplerate S 5x s s F 3ps 1E x RecordDuration 4 SCH TBA X treading DT Arms
62. uisition Mode 10 11 12 13 Use the Multipurpose a knob to select the High measurement Push the OK Add Measurement side bezel button Record the high and low measurements for example low 200 mV and high 3 52 V Repeat the procedure using 50 instead of 1 in step 4 This test checks random noise You do not need to connect any test equipment to the oscilloscope for this test 1 2 10 1 12 Disconnect everything connected to the oscilloscope inputs Push the front panel Default Setup button to set the instrument to the factory default settings This sets the oscilloscope to Channel 1 Full Bandwidth 1 MQ input impedance 100 mV div and 4 00 us div Set Gating to Off a Press the front panel Wave Inspector Measure button b Press the bottom bezel More button to select Gating c Press the side bezel Off Full Record button Select the RMS measurement a Press the bottom bezel Add Measurement button b Use the Multipurpose a knob to select the RMS measurement c Ifnecessary use the Multipurpose b knob to select the channel being tested as the source for the RMS measurement d Press the side bezel OK Add Measurement button Press the bottom bezel More button to select Statistics and then press the side bezel Reset Statistics button Press the front panel Menu Off button to remove the menus from the display Read the RMS Mean value This is the Sampled Mean Value SMV Press
63. utside range Error Sync Identifier Parity Checksum Trigger On Syne Identifier Data ID amp Data Wakeup Frame Sleep Frame or Error Maximum Data Rate 100 kbps MSO4000 and DPO4000 Series Specifications and Performance Verification 1 11 Specifications Table 1 4 Trigger specifications cont Characteristic Description FlexRay 4 Indicator bits Normal Frame Payload Frame Null Frame Sync Frame Startup Frame Identifier Trigger 11 bits of user specified data equal to not equal to lt gt less than lt greater than gt less than or equal to lt greater than or equal to gt Inside Range or Outside Range Cycle Count Trigger 6 bits of user specified data equal to Header Fields Trigger 40 bits of user specified data comprising Indicator Bits Identifier Payload Length Header CRC Cycle Count or equal to Data Trigger 1 to 16 Bytes of user specified data with 0 to 253 or don t care bytes of data offset including qualifiers of equal to not equal to lt gt less than greater than gt less than or equal to lt greater than or equal to gt Inside Range Outside Range End Of Frame User chosen types Static Dynamic DTS and All Error Header CRC Trailer CRC Null Frame static Null Frame dynamic Sync Frame Startup Frame Trigger On Start of Frame Indicator Bits Identifier Cycle Count Header Fields Data Identifier amp Data End of Frame or Err
64. utton The Thresholds menu should display MSOA4000 and DPO4000 Series Specifications and Performance Verification 19 20 21 22 23 24 25 26 27 28 Performance Verification Turn Multipurpose a knob and select the appropriate channel such as DO With the Fine front panel button turned off turn Multipurpose b knob and set the value to 4 00 V 4 0 V div To remove the menu from the display push the front panel Menu Off button Set the DC voltage source Vs to 4 4 V Wait 3 seconds Check the logic level of the corresponding digital channel in the display If the channel is a static logic level low change the DC voltage source Vs to 4 5 V Decrement Vs by 10 mV Wait 3 seconds and check the logic level of the corresponding digital channel in the display If the channel is at a static logic level low record the Vs value as V in the 4 V row of the test record If the channel is a logic level high or is alternating between high and low repeat this step decrement Vs by 10 mV wait 3 seconds and check for a static logic low until a value for V is found Push the front panel Trigger Menu button Push the Slope lower bezel button to change the slope to Rising Set the DC voltage source Vs to 3 6 V Wait 3 seconds Check the logic level of the corresponding digital channel in the display If the channel is a static logic level high change the DC voltage source Vs to 3 5 V Increment Vs
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