Tektronix MDO4014-3 Technical Reference Download

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MDO4000 Series

Mixed Domain Oscilloscopes

Speci

cations and Performance Veri

cation

ZZZ

Technical Reference

*P077058301*

077-0583-01

Summary of Contents for MDO4014-3

Page 1: ...xx MDO4000 Series Mixed Domain Oscilloscopes Specifications and Performance Verification ZZZ Technical Reference P077058301 077 0583 01...

Page 2: ......

Page 3: ...ports firmware version 2 94 and above for MDO4000 Series instruments Warning The servicing instructions are for use by qualified personnel only To avoid personal injury do not perform any servicing un...

Page 4: ...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 Tek...

Page 5: ...27 Test Record 29 Performance Verification Procedures 61 Self Test 62 Check Input Impedance Resistance 63 Check DC Balance 65 Check DC Gain Accuracy 67 Check Offset Accuracy 71 Check Analog Bandwidth...

Page 6: ...able 7 RF input specifications 17 Table 8 Display system specifications 20 Table 9 Interfaces and Input Output port specifications 21 Table 10 Data handling specifications 22 Table 11 Power supply sys...

Page 7: ...erve 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 prod...

Page 8: ...sult in damage to this product or other property Symbols and terms on the product These terms may appear on the product DANGER indicates an injury hazard immediately accessible as you read the marking...

Page 9: ...luating specifications See page 62 Self Test If the operating temperature changes by more than 10 C 18 F you must perform the SPC operation again Analog Signal Acquisition System Specifications The fo...

Page 10: ...50 termination and input terminated with 50 BNC terminator 0 2 div at 1 mV div with the input DC coupled set to 50 termination and input terminated with 50 BNC terminator 0 2 div with the input DC co...

Page 11: ...rm Number of waveforms for average acquisition mode 2 to 512 waveforms Default of 16 waveforms Measurement type DC Accuracy in Volts Average of 16 waveforms DC Gain Accuracy reading offset position of...

Page 12: ...rating information Delta volts between any two samples acquired with the same oscilloscope setup and ambient conditions DC gain accuracy reading 0 15 div 1 2 mV Refer to DC Gain Accuracy for temperatu...

Page 13: ...mV div DC to 175 MHz 5 mV div 10 V div DC to 500 MHz 2 mV div 4 98 mV div DC to 350 MHz MDO4054 X 1 mV div 1 99 mV div DC to 175 MHz 2 mV div 10 V div DC to 350 MHz MDO4034 3 1 mV div 1 99 mV div DC t...

Page 14: ...0 probe 10 mV div to 19 9 mV div TPP1000 probe 20 mV div to 49 8 mV div TPP1000 probe 50 mV div to 10 V div MDO4104 X 2 ns 1 ns 350 ps MDO4054 X 2 ns 1 ns 700 ps MDO4034 3 2 ns 1 ns 1 ns MDO4014 3 3 5...

Page 15: ...g or above 10 mV div All settings in the instrument can be manually time aligned using the Probe Deskew function from 125 ns to 125 ns with a resolution of 20 ps This specification does not pertain to...

Page 16: ...4014 3 2 5 S s 2 5 GS s Record Length Range 20 M 10 M 1 M 100 k 10 k 1 k Instrument 1 k 10 k 100 k 20 M MDO4104 X 2 channels enabled 400 ps 40 s 400 ps 400 s 400 ps 1 000 s Seconds Division range MDO4...

Page 17: ...cy specifications tp delta time measurement duration sec RD record length sample rate tsr 1 sample rate assume edge shape that results from Gaussian filter response Delta time measurement accuracy The...

Page 18: ...Source Sensitivity MDO4104 X Any input channel 50 path 0 40 div from DC to 50 MHz increasing to 1 div at oscilloscope bandwidth MDO4054 X MDO4034 3 MDO4014 3 Any input channel 50 path 1 mV div to 4 9...

Page 19: ...ypical 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 d...

Page 20: ...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...

Page 21: ...a or Address and Data Maximum Data Rate 10 Mbps SPI Data Trigger 1 to 16 bytes of user specified data Trigger On SS Active MOSI MISO or MOSI MISO Maximum Data Rate 50 Mbps CAN Data Trigger 1 to 8 byte...

Page 22: ...ing qualifiers of equal to not equal to less than greater than less than or equal to greater than or equal to inside range outside range Trigger on Word Select Data Maximum Data Rate 12 5 Mbps Left Ju...

Page 23: ...Address Packet Data Packet Handshake Packet Special Packet Error NOTE HIGH SPEED support available only on MDO4104 3 and MDO4104 6 models Ethernet Bit Rate 10BASE T 10 Mbps 100BASE TX 100 Mbps Trigge...

Page 24: ...mance of the digital channel It might also damage the input circuitry See the Absolute maximum input voltage specification Maximum Input Toggle Rate typical 500 MHz Maximum frequency sine wave input a...

Page 25: ...rris 4 1 ratio Input vertical range Vertical measurement range 30 dBm to DANL Vertical setting of 1 dB div to 20 dB div in a 1 2 5 sequence Attenuator settings from 0 to 45 dB in 5 dB steps Level disp...

Page 26: ...Flat Top 3 77 MDO4104 6 MDO4054 6 50 kHz to 5 MHz 130 dBm Hz 134 dBm Hz typical 5 MHz to 3 GHz 148 dBm Hz 152 dBm Hz typical 3 GHz to 6 GHz 140 dBm Hz 143 dBm Hz typical Displayed average noise level...

Page 27: ...55 dBc typical Image and IF rejection With 10 dBm reference level 78 dBm Residual spurious response With 25 dBm reference level and RF input terminated with 50 Power level trigger frequency and ampli...

Page 28: ...mm 6 21 in V 264 mm 10 4 in diagonal 6 bit RGB full color XGA 1024 x 768 TFT liquid crystal display LCD Display resolution 1024 X 768 XGA display resolution Luminance typical 400 cd m2 Waveform displa...

Page 29: ...ce Clock Out Reference Clock Out Outputs the 10 MHz oscilloscope reference clock Trigger Out A HIGH to LOW transition indicates that the trigger occurred Trigger output logic levels Characteristic Lim...

Page 30: ...cycle Real time clock A programmable clock providing time in years months days hours minutes and seconds Power Supply System Specifications The following table shows the power supply system specifica...

Page 31: ...C to 60 C 4 F to 140 F Humidity Operating High 40 C to 50 C 104 F to 122 F 10 to 60 relative humidity Low 0 C to 40 C 32 F to 104 F 10 to 90 relative humidity Nonoperating High 40 C to 60 C 104 F to 1...

Page 32: ...up 12 3 in 312 mm feet folded out handled folded up Width 17 3 in 439 mm from handle hub to handle hub Depth 5 8 in 147 mm from back of feet to front of knobs 6 1 in 155 mm from back of feet to front...

Page 33: ...10 dBm to 40 dBm and input level ranging from reference level to 30 dB below reference level Specifications exclude mismatch error at the preamp input and applies to both amplifying and bypass states...

Page 34: ...directly from the RF input on the MDO4000 Series oscilloscope Regulatory Compliance labeling WEEE European Union Recommended oscilloscopes MDO4000 Mixed Domain Oscilloscopes NOTE For best probe suppo...

Page 35: ...rification procedures for the specifications marked with the symbol These procedures cover all MDO4000 Series models Please ignore checks that do not apply to the specific model you are testing Print...

Page 36: ...MDO4000 Series oscilloscopes BNC to 0 1 inch pin adapter to connect the logic probe to the signal source BNC to 0 1 inch pin adapter female BNC to 2x16 01 inch pin headers Tektronix adapter part numb...

Page 37: ...put Impedance 1 M 1 V div 990 k 1 01 M Channel 2 Input Impedance 250 k 100 mV div 245 k 255 k 10 mV div 49 5 50 5 Channel 2 Input Impedance 50 100 mV div 49 5 50 5 10 mV div 990 k 1 01 M 100 mV div 99...

Page 38: ...ance 50 20 MHz BW 1 V div 100 mV 100 mV 1 mV div 0 2 mV 0 2 mV 2 mV div 0 4 mV 0 4 mV 5 mV div 1 mV 1 mV 10 mV div 2 mV 2 mV 20 mV div 4 mV 4 mV 100 mV div 20 mV 20 mV 500 mV div 100 mV 100 mV 1 V div...

Page 39: ...ance 50 20 MHz BW 1 V div 100 mV 100 mV 1 mV div 0 2 mV 0 2 mV 2 mV div 0 4 mV 0 4 mV 5 mV div 1 mV 1 mV 10 mV div 2 mV 2 mV 20 mV div 4 mV 4 mV 100 mV div 20 mV 20 mV 500 mV div 100 mV 100 mV 1 V div...

Page 40: ...ance 50 20 MHz BW 1 V div 100 mV 100 mV 1 mV div 0 2 mV 0 2 mV 2 mV div 0 4 mV 0 4 mV 5 mV div 1 mV 1 mV 10 mV div 2 mV 2 mV 20 mV div 4 mV 4 mV 500 mV div 100 mV 100 mV 100 mV div 20 mV 20 mV 1 V div...

Page 41: ...ance 50 20 MHz BW 1 V div 100 mV 100 mV 1 mV div 0 2 mV 0 2 mV 2 mV div 0 4 mV 0 4 mV 5 mV div 1 mV 1 mV 10 mV div 2 mV 2 mV 20 mV div 4 mV 4 mV 500 mV div 100 mV 100 mV 100 mV div 20 mV 20 mV 1 V div...

Page 42: ...1 5 20 MHz 1 V div 1 5 1 5 250 MHz 20 mV div 1 5 1 5 Channel 1 DC Gain Accuracy 0 V offset 0 V vertical position 50 Full 20 mV div 1 5 1 5 1 mV div 2 0 2 0 2 mV div 1 5 1 5 5 mV div 1 5 1 5 10 mV div...

Page 43: ...1 5 20 MHz 1 V div 1 5 1 5 250 MHz 20 mV div 1 5 1 5 Channel 3 DC Gain Accuracy 0 V offset 0 V vertical position 50 Full 20 mV div 1 5 1 5 1 mV div 2 0 2 0 2 mV div 1 5 1 5 5 mV div 1 5 1 5 10 mV div...

Page 44: ...applicable for the MDO4014 3 20 mV div 1 5 1 5 Channel 1 DC Gain Accuracy 0 V offset 0 V vertical position 1 M FULL 20 mV div 1 5 1 5 1 mV div 2 0 2 0 2 mV div 1 5 1 5 5 mV div 1 5 1 5 10 mV div 1 5 1...

Page 45: ...applicable for the MDO4014 3 20 mV div 1 5 1 5 Channel 3 DC Gain Accuracy 0 V offset 0 V vertical position 1 M FULL 20 mV div 1 5 1 5 1 mV div 2 0 2 0 2 mV div 1 5 1 5 5 mV div 1 5 1 5 10 mV div 1 5 1...

Page 46: ...6 V 3 V div 99 5 V 100 6 V 98 4 V 5 V div 99 5 V 98 00 V 101 0 V Channel 1 DC Offset Accuracy 20 MHz BW 1 M 5 V div 99 5 V 101 0 V 98 00 V 1 mV div 900 mV 895 3 mV 904 7 mV 1 mV div 900 mV 904 7 mV 89...

Page 47: ...1 M 5 V div 99 5 V 101 0 V 98 00 V 1 mV div 900 mV 895 3 mV 904 7 mV 1 mV div 900 mV 904 7 mV 895 3 mV 100 mV div 5 0 V 4 965 V 5 035 V Channel 4 DC Offset Accuracy 20 MHz BW 50 100 mV div 5 0 V 5 03...

Page 48: ...O4014 3 0 707 5 mV div 1 ns div Full BW 0 707 10 mV div 1 ns div Full BW 0 707 50 mV div 1 ns div Full BW 0 707 100 mV div 1 ns div Full BW 0 707 Channel 1 50 1 V div 1 ns div Full BW 0 707 MDO4104 3...

Page 49: ...O4014 3 0 707 5 mV div 1 ns div Full BW 0 707 10 mV div 1 ns div Full BW 0 707 50 mV div 1 ns div Full BW 0 707 100 mV div 1 ns div Full BW 0 707 Channel 2 50 1 V div 1 ns div Full BW 0 707 MDO4104 3...

Page 50: ...O4014 3 0 707 5 mV div 1 ns div Full BW 0 707 10 mV div 1 ns div Full BW 0 707 50 mV div 1 ns div Full BW 0 707 100 mV div 1 ns div Full BW 0 707 Channel 3 50 1 V div 1 ns div Full BW 0 707 MDO4104 3...

Page 51: ...O4014 3 0 707 5 mV div 1 ns div Full BW 0 707 10 mV div 1 ns div Full BW 0 707 50 mV div 1 ns div Full BW 0 707 100 mV div 1 ns div Full BW 0 707 Channel 4 50 1 V div 1 ns div Full BW 0 707 MDO4104 3...

Page 52: ...Hz limit 5 10 4 05 Full 8 30 6 08 250 MHz limit 5 10 4 05 Channel 3 20 MHz limit 5 10 4 05 Full 8 30 6 08 250 MHz limit 5 10 4 05 Channel 4 20 MHz limit 5 10 4 05 MDO4054 3 MDO4054 6 Full 8 13 8 13 25...

Page 53: ...417 ps MDO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 4 50 ns 5 mV 40 mV 2 52 ns 100 mV 800 mV 2 05 ns 500 mV 4 V 2 03 ns 1 V 4 V 4 01 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 45 0 ns 5 mV 40 mV 25...

Page 54: ...DO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 4 50 ns 5 mV 40 mV 2 52 ns 100 mV 800 mV 2 05 ns 500 mV 4 V 2 03 ns 1 V 4 V 4 01 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 45 0 ns 5 mV 40 mV 25 2 ns 100...

Page 55: ...DO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 4 50 ns 5 mV 40 mV 2 52 ns 100 mV 800 mV 2 05 ns 500 mV 4 V 2 03 ns 1 V 4 V 4 01 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 45 0 ns 5 mV 40 mV 25 2 ns 100...

Page 56: ...DO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 4 50 ns 5 mV 40 mV 2 52 ns 100 mV 800 mV 2 05 ns 500 mV 4 V 2 03 ns 1 V 4 V 4 01 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 45 0 ns 5 mV 40 mV 25 2 ns 100...

Page 57: ...54 ps 1 V 4 V 581 ps MDO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 6 99 ns 5 mV 40 mV 3 54 ns 100 mV 800 mV 2 73 ns 500 mV 4 V 2 69 ns 1 V 4 V 5 34 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 69 9 ns...

Page 58: ...54 ps 1 V 4 V 581 ps MDO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 6 99 ns 5 mV 40 mV 3 54 ns 100 mV 800 mV 2 73 ns 500 mV 4 V 2 69 ns 1 V 4 V 5 34 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 69 9 ns...

Page 59: ...54 ps 1 V 4 V 581 ps MDO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 6 99 ns 5 mV 40 mV 3 54 ns 100 mV 800 mV 2 73 ns 500 mV 4 V 2 69 ns 1 V 4 V 5 34 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 69 9 ns...

Page 60: ...54 ps 1 V 4 V 581 ps MDO 400 ns div Source freq 2 4 MHz 1 mV 8 mV 6 99 ns 5 mV 40 mV 3 54 ns 100 mV 800 mV 2 73 ns 500 mV 4 V 2 69 ns 1 V 4 V 5 34 ns MDO 4 s div Source freq 240 kHz 1 mV 8 mV 69 9 ns...

Page 61: ...0 1 V D4 4 V 3 78 V 4 22 V 0 V 0 1 V 0 1 V D5 4 V 3 78 V 4 22 V 0 V 0 1 V 0 1 V D6 4 V 3 78 V 4 22 V 0 V 0 1 V 0 1 V D7 4 V 3 78 V 4 22 V 0 V 0 1 V 0 1 V D8 4 V 3 78 V 4 22 V 0 V 0 1 V 0 1 V D9 4 V 3...

Page 62: ...r Frequency 2 GHz 1 MHz N A 113 dBc Hz Displayed Average Noise Level DANL Performance checks Low limit Test result High limit 50 kHz 5 MHz N A 130 dBm Hz All models 5 MHz 3 GHz N A 148 dBm Hz 3 GHz 4...

Page 63: ...034 3 MDO4014 3 100 MHz 3 GHz 1 dBm 1 dBm 0 dBm MDO4104 6 MDO4054 6 100 MHz 6 GHz 1 dBm 1 dBm 50 kHz 1 dBm 1 dBm 100 kHz 900 kHz 1 dBm 1 dBm 1 MHz 9 MHz 1 dBm 1 dBm All models 10 MHz 90 MHz 1 dBm 1 dB...

Page 64: ...rious Response Performance checks Low limit Test result High limit All models 50 kHz to 3 GHz N A 80 dBm 2 75 GHz to 4 5 GHz N A 78 dBm MDO4XX4 6 3 5 GHz to 6 0 GHz N A 78 dBm 56 MDO4000 Series Specif...

Page 65: ...z N A 68 dBm 600 MHz N A 68 dBm 700 MHz N A 68 dBm 800 MHz N A 68 dBm 900 MHz N A 68 dBm 1 GHz N A 68 dBm 1 1 GHz N A 48 dBm 1 2 GHz N A 48 dBm 1 3 GHz N A 48 dBm 1 4 GHz N A 48 dBm 1 5 GHz N A 48 dBm...

Page 66: ...Bm 600 MHz N A 68 dBm 700 MHz N A 68 dBm 800 MHz N A 68 dBm 900 MHz N A 68 dBm 1 GHz N A 68 dBm 1 1 GHz N A 48 dBm 1 2 GHz N A 48 dBm 1 3 GHz N A 48 dBm 1 4 GHz N A 48 dBm 1 5 GHz N A 48 dBm 1 6 GHz N...

Page 67: ...Bm 600 MHz N A 68 dBm 700 MHz N A 68 dBm 800 MHz N A 68 dBm 900 MHz N A 68 dBm 1 GHz N A 68 dBm 1 1 GHz N A 48 dBm 1 2 GHz N A 48 dBm 1 3 GHz N A 48 dBm 1 4 GHz N A 48 dBm 1 5 GHz N A 48 dBm 1 6 GHz N...

Page 68: ...48 dBm 1 9 GHz N A 48 dBm Generator signal frequency and Oscilloscope Center Frequency setting 2 GHz N A 48 dBm Auxiliary Trigger Output Performance checks Low limit Test result High limit High 1 M 2...

Page 69: ...PC operation again 3 You must connect the oscilloscope and the test equipment to the same AC power circuit Connect the oscilloscope and test instruments to a common power strip if you are unsure of th...

Page 70: ...stics perform an exhaustive verification of proper instrument function This verification may take several minutes i Verify that the status of all tests on the readout is Pass j Push the Menu button tw...

Page 71: ...o 1 M 4 Set the Vertical Scale to 10 mV division 5 Measure the input resistance of the oscilloscope with the calibrator Record this value in the test record 6 Repeat steps 4 and 5 for each vertical sc...

Page 72: ...s 4 through 6 9 Repeat the procedure for all remaining channels as follows a Push the front panel channel button to deselect the channel that you already tested b Connect the calibrator to the input f...

Page 73: ...zontal Scale to 1 ms per division 6 Set the Acquisition mode to Average as follows a Push the front panel Acquire button b Push the Average side bezel button c Make sure that the number of averages is...

Page 74: ...g 13 Repeat the tests at 1 M impedance as follows a Push the front panel channel 1 button b Set the Termination input impedance to 1M c Repeat steps 4 through 12 14 Repeat the procedure for all remain...

Page 75: ...The Termination input impedance is set to 1 M and channel 1 input is selected NOTE 50 termination testing steps 4 through 14 is required only for MDO4104 3 and MDO4104 6 models 1 M termination testin...

Page 76: ...llows a Push the Trigger Menu button on the front panel b Push the Source lower bezel button c Select the AC Line as the trigger source 9 Set the Vertical Scale to 1 mV division 10 Record the negative...

Page 77: ...V 90 mV 45 mV 45 mV 20 mV 180 mV 90 mV 90 mV 50 mV 450 mV 225 mV 225 mV 63 5 mV 571 5 mV 285 75 mV 285 75 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 V...

Page 78: ...d b Move the DC voltage source connection to the next channel input to be tested c Starting from step 9 repeat the procedure for each channel 15 Repeat tests at 1 M impedance a Set the calibrator to 1...

Page 79: ...Default Setup button 3 Set the Acquisition mode to Average as follows a Push the front panel Acquire button b Push the Mode lower bezel button if not already selected c Push the Average side bezel but...

Page 80: ...ted as follows a Push the front panel Wave Inspector Measure button b Push the Add Measurement lower bezel button c Select the Mean measurement d Push the OK Add Measurement side bezel button 12 View...

Page 81: ...ave b Push the front panel channel 1 button c Set the Termination input impedance to 50 4 Set the Acquisition mode to Sample as follows a Push the front panel Acquire button b Push the Mode lower beze...

Page 82: ...frequency for the bandwidth and model desired as shown in the following worksheet 11 Record the peak to peak measurement as follows a View the mean Vp p of the signal Call this value Vbw pp b Enter th...

Page 83: ...the test record to calculate the Gain at bandwidth with the following equation Gain Vbw pp Vin pp To pass the performance measurement test Gain should be 0 707 Enter Gain in the test record 13 Repeat...

Page 84: ...to select Statistics b Push the side bezel Reset Statistics button 6 Read and make a note of the RMS Mean value This is the Sampled Mean Value SMV 7 Set the Acquisition mode to Average as follows a P...

Page 85: ...ce to 1 M c Push the bottom bezel Bandwidth button d Push the side bezel 250 MHz button e Push the front panel Waveform Inspector Measure button f Repeat steps 5 through 12 14 Repeat the tests at 20 M...

Page 86: ...p button 4 Set the impedance to 50 as follows a Push the front panel channel 1 button b Set the Termination to 50 5 If it is adjustable set the time mark amplitude to approximately 1 Vp p 6 Set the Ve...

Page 87: ...er 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 ce...

Page 88: ...50 impedance as follows a Set the sine wave generator output impedance to 50 b Push the channel 1 button to display the channel 1 menu c Set the Termination input impedance to 50 4 Set the trigger so...

Page 89: ...ve the side bezel menu c Wait five or 10 seconds for the oscilloscope to acquire all of the samples d Verify that the Std Dev is less than the upper limit shown in the test record e Enter the reading...

Page 90: ...the Required Equipment table See Table 15 on page 28 c Connect channel D0 to both the corresponding signal pin and to a ground pin on the adapter WARNING The generator is capable of providing dangero...

Page 91: ...crement Vs by 10 mV wait 3 seconds and check for a static logic high until a value for Vs is found 8 Click the lower bezel Slope button to change the slope to Falling 9 Set the DC voltage source Vs to...

Page 92: ...3 seconds Check the logic level of the channel D0 signal display If the signal level is a static logic high change the DC voltage source Vs to 3 5 V 18 Increment Vs by 10 mV Wait 3 seconds and check...

Page 93: ...SMA coaxial cable see the following figure 2 Set the generator for a 2 GHz 0 dBm signal 3 Initial oscilloscope setup a Push the front panel Default Setup button b Turn Channel 1 off c Push the front...

Page 94: ...Push the side bezel Readout button to select Delta j Set the reference level to 0 dbm as follows Push the front panel Ampl button Push the side bezel Ref Level button Set the reference level to 0 dBm...

Page 95: ...e test record 6 Repeat the check at 1 MHz a Change the span to 5 MHz b Change the resolution bandwidth RBW to 50 kHz c Set marker a to the signal peak d Set marker b to 1 MHz e Note the bottom value i...

Page 96: ...MHz to 3 GHz all models 3 GHz to 4 GHz MDO4104 6 and MDO4054 6 only 4 GHz to 6 GHz MDO4104 6 and MDO4054 6 only NOTE If the specific measurement frequency results in measuring a residual spur that is...

Page 97: ...thod to Average g Set the reference level to 25 0 dBm as follows Push the front panel Ampl button Push the side bezel Ref Level button Set the Ref Level to 25 0 dBm h Set the start and stop frequency...

Page 98: ...To Center side bezel button e Set the span to 10 MHz as follows Push the side bezel Span button Set the Span to 10 MHz f Record the highest noise value in dBm Hz in the test record and compare it to t...

Page 99: ...Set the stop frequency to 6 GHz b Set the start frequency to 4 GHz c Set Manual Marker a at the frequency of the highest noise ignoring any spurs d Set the center frequency as follows Push the R To Ce...

Page 100: ...head Power splitter Adapters and cables as shown in the following figure WARNING The generator is capable of providing dangerous voltages Be sure to set the generator to off or 0 volts before connect...

Page 101: ...y to 0 Hz Push the side bezel Stop button Set the stop frequency to 1 MHz c Set the generator to provide a 50 kHz 10 dBm signal d At 50 kHz determine the test result as follows Note the reading on the...

Page 102: ...lt as follows Note the reading on the power meter and the readout for the Reference marker on the oscilloscope Calculate the difference between the two readings This is the test result k In the test r...

Page 103: ...e the frequency range as follows Change the stop frequency to 6 1 GHz Change the start frequency to 99 MHz u Set the generator to provide a 100 MHz 10 dBm signal v Step the generator in 100 MHz interv...

Page 104: ...e two readings This is the test result g In the test record enter the greatest result determined within this frequency range 100 kHz 900 kHz h Change the frequency range as follows Change the stop fre...

Page 105: ...ange the start frequency to 99 MHz q Set the generator to provide a 100 MHz 0 dBm signal r Step the generator in 100 MHz intervals through frequencies from 100 MHz to 2 9 GHz At each interval determin...

Page 106: ...start frequency to 0 Hz Push the side bezel Stop button Set the stop frequency to 1 MHz c Set the generator to provide a 50 kHz 15 dBm signal d At 50 kHz determine the test result as follows Note the...

Page 107: ...r in 10 MHz intervals through frequencies from 10 MHz to 90 MHz At each interval determine the test result as follows Note the reading on the power meter and the readout for the Reference marker on th...

Page 108: ...Third Order Intermodulation Distortion This check verifies that the oscilloscope meets the specification for Third Order Intermodulation Distortion WARNING The generators are capable of providing dang...

Page 109: ...rovide a 2 735 GHz 5 dBm signal at the RF input of the oscilloscope 3 Set generator 2 to provide a 2 755 GHz 5 dBm signal at the RF input of the oscilloscope 4 Initial oscilloscope setup a Push the fr...

Page 110: ...anel button Push the side bezel Vertical button Set the scale to 10 dB division i Set the Ref Level as follows Push the side bezel Ref Level button and set the Ref Level to 0 dBm j Push the front pane...

Page 111: ...dBm signal at the RF input of the oscilloscope a Set the Center Frequency to 4 5 GHz b Set marker a to the peak of the generator 1 signal 4 49 GHz c Check for peaks at two frequencies 20 MHz lower fr...

Page 112: ...tically set the reference level correctly 4 Check in the range of 50 kHz to 3 GHz as follows a Push the front panel Freq Span button Push the side bezel Start button Set the start frequency to 50 kHz...

Page 113: ...ave the capacity to hook up all four channels at once you can move the connector to each channel in turn 3 Set the generator to provide a 50 kHz 40 dB 1 Vp p sine wave signal 4 Initial oscilloscope se...

Page 114: ...the Channel 1 signal that appears in the RF display See the following figure c Record the amplitude of the Channel 1 signal in the test record Make sure that it is within the specified limit 7 Repeat...

Page 115: ...the front panel Wave Inspector Measure button b Push the Add Measurement lower bezel button c Select the Low measurement d Push the OK Add Measurement side bezel button e Enter the Low measurement rea...

Page 116: ...s as shown in the following figure WARNING The generator is capable of providing dangerous voltages Be sure to set the generator to off or 0 volts before connecting disconnecting and or moving the tes...

Page 117: ...m signal d Note the reading on the power meter and the readout for the Reference marker on the oscilloscope See the following figure e The absolute difference between the two readings should be small...

Page 118: ...vide a 5 5 GHz 45 dBm signal Set the reference level to 40 dBm Compare the MDO4000 and the power meter readings as before The absolute difference between the readings should be 2dB or less If the MDO4...

Page 119: ...the TPA N PRE preamplifier On the MDO4000 for the Mode select Auto h Set the reference level to 40 0 dBm as follows Push the front panel Ampl button Push the side bezel Ref Level button Set the Ref Le...

Page 120: ...To Center side bezel button e Set the span to 10 MHz as follows Push the side bezel Span button Set the Span to 10 MHz f Record the highest noise value in dBm Hz in the test record and compare it to t...

Page 121: ...GHz b Set the start frequency to 4 GHz c Set Manual Marker a at the frequency of the highest noise ignoring any spurs d Set the center frequency as follows Push the R To Center side bezel button e Set...

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