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Un buon manuale d’uso
Le regole impongono al rivenditore l'obbligo di fornire all'acquirente, insieme alle merci, il manuale d’uso Agilent Technologies E7403A. La mancanza del manuale d’uso o le informazioni errate fornite al consumatore sono la base di una denuncia in caso di inosservanza del dispositivo con il contratto. Secondo la legge, l’inclusione del manuale d’uso in una forma diversa da quella cartacea è permessa, che viene spesso utilizzato recentemente, includendo una forma grafica o elettronica Agilent Technologies E7403A o video didattici per gli utenti. La condizione è il suo carattere leggibile e comprensibile.
Che cosa è il manuale d’uso?
La parola deriva dal latino "instructio", cioè organizzare. Così, il manuale d’uso Agilent Technologies E7403A descrive le fasi del procedimento. Lo scopo del manuale d’uso è istruire, facilitare lo avviamento, l'uso di attrezzature o l’esecuzione di determinate azioni. Il manuale è una raccolta di informazioni sull'oggetto/servizio, un suggerimento.
Purtroppo, pochi utenti prendono il tempo di leggere il manuale d’uso, e un buono manuale non solo permette di conoscere una serie di funzionalità aggiuntive del dispositivo acquistato, ma anche evitare la maggioranza dei guasti.
Quindi cosa dovrebbe contenere il manuale perfetto?
Innanzitutto, il manuale d’uso Agilent Technologies E7403A dovrebbe contenere:
- informazioni sui dati tecnici del dispositivo Agilent Technologies E7403A
- nome del fabbricante e anno di fabbricazione Agilent Technologies E7403A
- istruzioni per l'uso, la regolazione e la manutenzione delle attrezzature Agilent Technologies E7403A
- segnaletica di sicurezza e certificati che confermano la conformità con le norme pertinenti
Perché non leggiamo i manuali d’uso?
Generalmente questo è dovuto alla mancanza di tempo e certezza per quanto riguarda la funzionalità specifica delle attrezzature acquistate. Purtroppo, la connessione e l’avvio Agilent Technologies E7403A non sono sufficienti. Questo manuale contiene una serie di linee guida per funzionalità specifiche, la sicurezza, metodi di manutenzione (anche i mezzi che dovrebbero essere usati), eventuali difetti Agilent Technologies E7403A e modi per risolvere i problemi più comuni durante l'uso. Infine, il manuale contiene le coordinate del servizio Agilent Technologies in assenza dell'efficacia delle soluzioni proposte. Attualmente, i manuali d’uso sotto forma di animazioni interessanti e video didattici che sono migliori che la brochure suscitano un interesse considerevole. Questo tipo di manuale permette all'utente di visualizzare tutto il video didattico senza saltare le specifiche e complicate descrizioni tecniche Agilent Technologies E7403A, come nel caso della versione cartacea.
Perché leggere il manuale d’uso?
Prima di tutto, contiene la risposta sulla struttura, le possibilità del dispositivo Agilent Technologies E7403A, l'uso di vari accessori ed una serie di informazioni per sfruttare totalmente tutte le caratteristiche e servizi.
Dopo l'acquisto di successo di attrezzature/dispositivo, prendere un momento per familiarizzare con tutte le parti del manuale d'uso Agilent Technologies E7403A. Attualmente, sono preparati con cura e tradotti per essere comprensibili non solo per gli utenti, ma per svolgere la loro funzione di base di informazioni e di aiuto.
Sommario del manuale d’uso
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Pagina 1
Sign al Anal ysi s Meas ure ment Gu ide Agilen t T ech no logies EMC Se ries Analyzer s This gu ide documents firmware revision A.08.xx This m a nual pr ovides do c ume ntatio n for the fo llowing instru ments : E7401 A (9 kHz - 1.5 GHz) E7402 A (9 kHz - 3.0 GH z) E7403 A (9 kHz - 6.7 GH z) E7404A (9 kH z - 13.2 G Hz ) E7405A (9 kH z - 26.5 G Hz ) [...]
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Pagina 2
2 Noti ce The i nformation c ontained in this d ocument is s ubject to chang e witho ut notic e. Agilent T echnologies makes no warra nty of any kind with regard to this materi al, inc luding but not limi ted to , the im plied warrant ies of merchantabil ity and fit ness for a partic ular pu rpose. Agilent T echno l og ie s shall not be li ab le fo[...]
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Pagina 3
3 W ARNING This is a Safety Class 1 Product ( provided with a protective earth ground i ncorporated in the power cord). The mains plug shall be in serted only i n a socket out let provided wit h a protected eart h contact. Any interr uption of the protect ive conductor insi de or outside of the pr oduct is li kely to make t he produc t dangerous. I[...]
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Pagina 4
4 LIMIT A TION OF W ARRANTY The fo re g oin g war ra nty sh al l n o t appl y to de fe ct s re su l tin g fr om improper o r ina dequate maintenan ce by Buyer , Buyer -s upplied softwar e or inte rfa cing, una uthor ized modifi cati on or misuse, op er ation outsid e of the environmenta l sp ec ifi cations f or the p ro duct, or improp er site p re[...]
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Pagina 5
Co nt e nt s 5 1. Mak ing B asic Me asurem ent s Wh a t i s i n T his C hap ter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Te st E qui pm en t . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . [...]
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Pagina 6
6 Con tent s Tracki ng Generat or Unleveled Condi tion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 6 Me as uri ng De vi ce Ba nd wi dth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 Me as uri ng Sto p Ba nd A tten ua ti on Us in g L og S wee[...]
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7 1 Making Bas ic Measurements[...]
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8 Ch a pt er 1 Making Basic M easurements What i s i n T his Chap ter What is in This Chapt er Thi s ch ap ter d e mo n st ra te s bas ic a n aly z e r m easu re m e n t s wi th examples of typ ical measur ements; each m easurement f ocuses o n differ ent func tions. T he measur ement procedures c overe d in this cha p t e r are li ste d be lo w . [...]
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Pagina 9
Chapter 1 9 Making B asic Measurements What is in This Chapter Te s t E q u i p m e n t T e s t E q ui pm en t S pec if i cat io ns Re co m m end e d Mo de l Signal Sour ces S i g n a l G e n e r a t o r ( 2 ) 0 . 2 5M H z t o 4 . 0G H z Ext Ref Input E4433B or E443XB ser ies Adapters T ype-N (m) to BN C (f) (3) 1250-0780 T er m inati on , 50 Ω T[...]
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Pagina 10
10 Ch a pt er 1 Making Basic M easurements Compari ng Signal s C omp ari n g S ign als Using the analyzer , you c an easily compare frequency a nd amplitude differ ences bet ween signal s, s uch as ra dio or te levisi on signal s pectr a. The anal yzer del ta marker f uncti on lets y ou compare two signa ls when both ap pear on t he screen at one t[...]
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Pagina 11
Chapter 1 11 Making B asic Measurements Comp ari ng Sign als Figure 1- 1 Placing a Marker on the 10 MH z Signal 9. Pre ss Marker , Delta , to a c tivate a s ec ond marker at the p os i tio n of t he fir st ma rke r . 10. Move the second marker to another s ignal pea k using the front- panel knob , or by pr essing Peak Search and then eit her Next P[...]
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Pagina 12
12 Ch a pt er 1 Making Basic M easurements Compari ng Signal s Figure 1 -2 Using the Marker Del ta Function Signal Comparison Example 2: Measure the fr equency and ampl itude di fference b etween tw o signals that do not a ppear on the screen a t one ti me. (Thi s techniq ue is us eful for harmoni c distor ti on tests when narro w span a nd narrow [...]
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Pagina 13
Chapter 1 13 Making B asic Measurements Comp ari ng Sign als 10. Pr ess Mar ker , Delta to anchor the posi tion of the fi rst marker a nd ac tivat e a s econ d mark er . 11 . Pr ess FREQUENCY , Ce nter Fr eq , a nd the ( ↑ ) key to in crea se the ce nt er frequency by 1 0 MHz. The first marker m oves to the lef t edge of the scree n, at the ampli[...]
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Pagina 14
14 Ch a pt er 1 Making Basic M easurements Resolvi ng Sign als of Equal Amplitude Resolving Sign als of E qual Amplitude T w o equal -amplitude i nput si gnals that a re close in fr equency c an ap pear as a sin gle si g nal tr ace on the ana lyzer di spl ay . R espo nding to a singl e-freq uency signa l, a swept-tuned a nalyz er traces out the sha[...]
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Pagina 15
Chapter 1 15 Making B asic Measurements Resolvi ng S ignals of Equal Ampl itude Resolving Signals Exam ple: Resolve tw o signals of equal amplitude w ith a frequenc y separatio n of 100 kHz. 1. Connect two sourc es to the analyzer i nput a s shown in Figure 1 -4 . Figure 1-4 Setup for O btainin g T wo Signals 2. Set one s ourc e to 300 MHz. Set the[...]
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Pagina 16
16 Ch a pt er 1 Making Basic M easurements Resolvi ng Sign als of Equal Amplitude Figure 1-5 Unresolved S ignals of Equal Amplitude 4. Since the resolut ion bandwidth must be l ess than or eq ual to the frequency sep arati on of the two signal s, a resoluti on bandwidth of 100 kHz m us t be used. Chang e t h e r es o l ut io n ban d wid t h to 10 0[...]
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Pagina 17
Chapter 1 17 Making B asic Measurements Resolvi ng S ignals of Equal Ampl itude 5. Decreas e the vi deo bandwidth to 1 0 kH z, b y pressing Vide o B W , 10, kHz . T wo sig nal s ar e now vis ibl e as sh o w n in Figur e 1 -7 . Use the front- panel knob or step keys t o f urther re duce the r esolution bandwidth a nd better res olve the signals. Fig[...]
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18 Ch a pt er 1 Making Basic M easurements Resolvi ng Small Si gnals Hi dden b y Lar ge Signals Resolvin g Sm all Signals Hidde n by Large Signals When deal ing with the resol utio n of si gnals that are c lose tog ether a nd not equ al in amplitude, y ou must consider the shape of the I F filt er of the a n alyz e r , as we l l as i ts 3 dB ban d [...]
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Chapter 1 19 Making B asic Measurements Resolvin g Small Sign als Hidden by Lar ge Sign als Resolving Signals Exam ple: Reso l ve two inp ut si gna ls with a fre q ue ncy se p arat ion of 155 kHz and an am plitu de separation of 60 dB. 1. Connect two sourc es to the analyzer i nput a s shown in Figure 1 -9 . Figure 1-9 Setup for O btainin g T wo Si[...]
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20 Ch a pt er 1 Making Basic M easurements Resolvi ng Small Si gnals Hi dden b y Lar ge Signals 5. Set the 3 00 MHz signal to the re ference leve l by pressi ng Mk r → and then Mkr → Ref Lvl . If a 10 kHz filter w ith a typic a l sha pe f actor of 1 5:1 i s us ed, the filt er wil l hav e a ba ndwi dth o f 150 kHz at the 60 dB poin t . Th e half[...]
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Chapter 1 21 Making B asic Measurements Resolvin g Small Sign als Hidden by Lar ge Sign als 7. Set the resol ution bandwidth to 30 kH z by pressi ng BW/A vg , Res BW , 30, kHz . When a 30 kHz filter is used, the 60 dB band width could b e as wid e as 450 kHz. Since the hal f-bandwidth ( 225 kHz) is wider than the freq u e n cy sep ara tio n , the s[...]
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Pagina 22
22 Ch a pt er 1 Making Basic M easurements Making Bet ter Frequenc y Measurements Maki ng Bett er Fr equen cy Meas ure ments A buil t-in fr equ e n cy cou n ter incre a ses the re so l u t io n an d ac cura cy of the f requency rea dout. Wh en using thi s funct ion, if t he r atio of the resolu t i on ban dw id t h to the sp an is t o o sma ll (le [...]
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Chapter 1 23 Making B asic Measurements Maki ng Better Frequenc y Measur ements NOTE Ma rker count pr operly functi ons onl y on CW s ignals or discrete s pectral component s. The marker must be > 26 dB abov e the noi se. 9. Increa se the counte r resolution b y pres sing Re solu tion an d t h e n enteri ng the des ired res olution using the s t[...]
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Pagina 24
24 Ch a pt er 1 Making Basic M easurements Decreasing the Frequency Span Ar ound t he Signal Decreas i ng the Freq uency Spa n Around the Signal Us ing th e ana ly ze r s ig nal trac k f un ct io n, y ou c an qui ckly d ec r eas e th e span while keeping the si gnal at center frequenc y . This is a fast way to take a c loser l ook at the area aroun[...]
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Chapter 1 25 Making B asic Measurements Decreasing the Frequency Span Around the Signal Figure 1- 14 Detected Signal 8. T urn on the f requency tracking f unction by press FREQUENCY an d Signal T rack and the si gnal will move to the center o f the sc reen, i f it is not a lrea dy posi tioned ther e. Se e figure Fig ure 1- 15 . (N ot e that the mar[...]
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26 Ch a pt er 1 Making Basic M easurements Decreasing the Frequency Span Ar ound t he Signal 9. Reduce span a nd resoluti on bandwid th to zoom i n on the m arked si g nal by p re s si ng SP AN , Spa n , 20 0, kHz . If the span chang e is la rge e nough, span wi ll decr ease in steps a s automatic zoom is completed . See Fig ure 1- 16 . Y ou can a [...]
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Pagina 27
Chapter 1 27 Making B asic Measurements T racki ng Drif ti ng Sign als T rackin g Driftin g Signals The signal track func tion is usef ul f or tracking drifti ng signals th at drift r elativel y slowly . T o place a marker on the si gnal you w ish to track, use P eak S earch . Pressing FREQUENCY , Sig nal T rack (On) wil l bring that signa l to the[...]
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Pagina 28
28 Ch a pt er 1 Making Basic M easurements T racki ng Drif t ing Signals Figure 1 - 1 7 Signal Wit h Default Span 4. Press Peak Search . 5. Set the spa n to 10 M H z by pre ssi n g SP AN , Span , 10, MH z . See Fi g ur e 1- 18 . Figure 1 - 1 8 Signal Wi th 10 MHz S pan 6. Press SP AN , Spa n Zo om , 500, kHz . Notice t hat the si gnal has been held[...]
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Pagina 29
Chapter 1 29 Making B asic Measurements T racki ng Drif ti ng Sign als Figure 1- 19 Signal W ith 50 0 k Hz Span 7. T une the frequency of the si gnal generator in 10 kHz increments. Notice that the center frequency of the a nalyzer also changes i n 10 k Hz increments, cent ering the signal with each i ncr ement. See Figu r e 1- 20 . Note that the c[...]
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Pagina 30
30 Ch a pt er 1 Making Basic M easurements T racki ng Drif t ing Signals 8. The signal frequenc y drift can be r ead from the scree n if both the sig nal t rac k a nd mark er d el t a fu nc ti o ns are act i ve. Se t t he a nal yze r and si gna l gen e r at o r as fo l lo w s : a. Pre ss Marker , Delta . b. T une the fre quency of the signa l gener[...]
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Pagina 31
Chapter 1 31 Making B asic Measurements T racki ng Drif ti ng Sign als d. Set the c enter f requency to 300 MHz by pressing FREQUENCY , Ce nter Fre q , 300, MH z . See Fi gure 1 -22 . Figure 1-22 Signal W it h Default Span 4. Pre ss Peak S earch . 5. Set the s pan to 10 MHz b y pressing SP A N , Sp a n , 10, MH z . See Figu r e 1- 23 . Figure 1-23 [...]
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Pagina 32
32 Ch a pt er 1 Making Basic M easurements T racki ng Drif t ing Signals 6. Press SP AN , Spa n Zo om , 500, kHz . Notice t hat the si gnal has been held in the c enter o f the d isplay . See Figu re 1- 24 . Figure 1 -24 Signal Wit h 5 00 KHz Span 7. T urn off t he sig nal track func tion b y pressing FREQUENCY , Sign al T rac k (Off ). 8. T o meas[...]
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Pagina 33
Chapter 1 33 Making B asic Measurements T racki ng Drif ti ng Sign als Figure 1-25 V iewing a Dri fting S ignal W it h Max Hold and Clear W rite[...]
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Pagina 34
34 Ch a pt er 1 Making Basic M easurements Measuring Lo w Level Signals Measur ing Low L evel S ignals The abili ty of the analyzer to measure low level s ignals is limited by t he noise g enerated i nside t he analyzer . A signal m ay be masked b y the no ise flo or so th at it is n ot vis ibl e. Thi s s ens itiv ity to low le vel sign als is affe[...]
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Pagina 35
Chapter 1 35 Making B asic Measurements Measuring Lo w Le vel Signals 10. Reduce the s pan to 1 MHz. Press SP AN , Sp an , and then use the step- down key ( ↓ ) until the spa n is set to 1 MHz. See Figu re 1 -26 . Figure 1-26 Low-Level Sign al 11 . Pr ess AMPL I TUDE , Attenuation . Pr e ss the st e p-u p key ( ↑ ) to select 20 dB a tte nuation[...]
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Pagina 36
36 Ch a pt er 1 Making Basic M easurements Measuring Lo w Level Signals 12. T o see t h e s ig na l m ore cle a rly , ent e r 0 dB . Ze ro de ci bels of attenuat ion makes the s ignal more visib le. See Fig ure 1- 28 . Figure 1 -28 Using 0 dB Attenuation CAUTIO N Before connec ting ot her sig nals to t he anal yzer input , increa se the RF attenuat[...]
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Pagina 37
Chapter 1 37 Making B asic Measurements Measuring Lo w Le vel Signals 9. Place the signa l at center f requency by pressing Peak Search , Marker → , Mk r → CF . 10. Pr ess BW/Avg , Res BW , a n d th e n ↓ . Th e low leve l sig nal app e a rs more cl early because the noi se l evel is reduced. As shown i n Figu r e 1-29 . A # m ark appears nex[...]
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Pagina 38
38 Ch a pt er 1 Making Basic M easurements Measuring Lo w Level Signals 3. On the anal yzer , perform a f acto ry preset by pressi ng Preset , Factor y Pres et ( if p r es e nt) . 4. Set the c enter f requency of the ana lyzer to 300 MHz by pressing FREQUENCY , Cen ter Freq , 300, MHz . 5. Set the spa n to 5 MH z by pre ssing SP AN , Sp an , 5, MHz[...]
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Pagina 39
Chapter 1 39 Making B asic Measurements Measuring Lo w Le vel Signals NO TE The video band width must be s et wi der than the resolut ion band width w hen m eas ur ing im pu ls e n oi se l e vel s. Figu r e 1-31 D ecr easing V ide o Band width Measuring Low Level S ignals Example 4: If a s ignal l evel i s very close t o the noise fl oor , video av[...]
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Pagina 40
40 Ch a pt er 1 Making Basic M easurements Measuring Lo w Level Signals 1. Connect a s ignal g enerator to the ana lyzer input. 2. Set the signal gene rator freq uency to 300 M Hz with an amplitude of − 80 dBm. 3. On the anal yzer , perform a f acto ry preset by pressi ng Preset , Factor y Pres et ( if p r es e nt) . 4. Set the c enter f requency[...]
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Pagina 41
Chapter 1 41 Making B asic Measurements Measuring Lo w Le vel Signals 11 . T o set the num ber of samples , use the numeric keypad. For example, press Average (On) , 25, Ent er . As sh o w n in Fig ure 1- 33 . Du ri ng av era gi n g, th e cur r ent sa mple numbe r ap pe ar s at the l e ft side of the g ratic ule. The number of s am ples eq uals the[...]
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Pagina 42
42 Ch a pt er 1 Making Basic M easurements Ident ifying Dist ortion Produ cts Identifyin g Dist ortion Pro ducts Distortion from the Analyzer Hi gh l eve l inp ut s ign al s m ay c aus e a nal yze r dis tor tio n pro duc ts th at coul d mask the r eal disto rtion measured on the i nput sig nal. Using trace 2 and t he RF attenuator , you c an dete r[...]
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Pagina 43
Chapter 1 43 Making B asic Measurements Ident ifying Di sto rtion Produ cts Figure 1-34 Harmonic Distortion 8. Change the center f requen cy to the va lue of one of the o bserved har mon i cs by pre ssi n g Peak Search , Next P eak , Mark er → , Mkr → CF . 9. Chan ge t he span to 50 MH z: p ress SP AN , Spa n , 50, MHz . 10. E nsu re t h at the[...]
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Pagina 44
44 Ch a pt er 1 Making Basic M easurements Ident ifying Dist ortion Produ cts 12. T o deter mine whether the har monic distor tion p roducts are generated by the analy zer , fir st save the screen d ata in t race 2 as fo ll ows : a. Pre ss T race/View , T race (2) , then Clear W rite . b. Allow the tr ace to update (t wo sweeps) and press T race/Vi[...]
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Pagina 45
Chapter 1 45 Making B asic Measurements Ident ifying Di sto rtion Produ cts Figure 1-37 No Harmonic Distortion Third-Order Inter mod ulation Distortion T wo-tone, third- order inter modulation d istort ion is a common test i n communication s ystems. When two signal s are pr esent i n a non-li near syst e m , the y ca n in t e rac t an d cre a te t[...]
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Pagina 46
46 Ch a pt er 1 Making Basic M easurements Ident ifying Dist ortion Produ cts Figure 1 -38 Third -Order Int ermodulation E quipment Setup NOTE The combiner shoul d ha ve a high deg ree of isolatio n between the two input po rt s so th e sour ce s do n o t in ter mod ul ate. 2. Set one source (signal genera tor) to 300 MHz and the other sour ce to 3[...]
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Pagina 47
Chapter 1 47 Making B asic Measurements Ident ifying Di sto rtion Produ cts The anal yzer automati cally sets the attenuati on so that a s ignal at th e r ef ere n c e le v el wi ll b e a ma xi mu m o f − 30 d B m at t h e in pu t mixe r . 10. Pr ess BW/Avg , Res BW , and then use the step-d own key ( ↓ ) to redu ce the re solution b andwidth u[...]
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Pagina 48
48 Ch a pt er 1 Making Basic M easurements Ident ifying Dist ortion Produ cts Figure 1 -40 Measuring t he Distortion Product[...]
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Pagina 49
Chapter 1 49 Making B asic Measurements Measuring Signal- to -No ise Me as ur ing Si gn al - to- N oi se The signal -to-no ise measurement procedure below may be a dapted to mea su re an y sig nal i n a s y st em if th e s ig nal (car rier ) i s a d is c ret e ton e. If th e sig nal in yo ur syst em is mod ulate d, it will be nec essar y to m odi f[...]
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Pagina 50
50 Ch a pt er 1 Making Basic M easurements Measuring Si gnal- t o-Noise 11 . P ress More , Funct ion , Ma r k er N o is e to v iew the r es ults of the s i gna l t o noise measurement. See Fig ure 1- 41 . Figure 1 -41 Measuring t he Signal-to-Noise Read the s ignal-to- nois e in dB/Hz, t hat is with the noise v alue determined for a 1 Hz noise band[...]
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Pagina 51
Chapter 1 51 Making B asic Measurements Making Noise Measurements Making Noise Measurements There are a variety of way s to measur e noise p ower . The firs t decisi on you must make i s whether you want to measure no ise power at a specific frequenc y or the total p ower over a speci fied f requency range , for exa mple over a channel bandw idth. [...]
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Pagina 52
52 Ch a pt er 1 Making Basic M easurements Making No ise Measurements Fi gu re 1 -42 Sett in g the At ten ua t ion 8. Activate the nois e marker by pressi ng Ma rker , More , Fu nct ion , Mar ker Noi se . Note that t he disp lay det ection automat ically c hanged to “ Av g ” which can b e manually set by p ressing Det/D emod, Average (V ideo/RM[...]
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Pagina 53
Chapter 1 53 Making B asic Measurements Making Noise Measurements Figure 1-43 Activating the Noise Marker 9. The noi se marker v alue is based on t he mean of 5 % of t he total number of sweep poi nts centered at the marker . The points aver aged span one-half of a d ivision. T o see the effect , move the marker to the 50 MH z sig n al by pr e ssin[...]
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Pagina 54
54 Ch a pt er 1 Making Basic M easurements Making No ise Measurements NOTE Notice the video b andwidth cha nged to 1 00 kHz. The r atio between the video b andwidth (VBW) and the resolu tion bandwidth (RBW) must be ≥ 10/ 1 to maintai n the acc uracy of t he measure ment. Figu re 1-45 Increa sed R es oluti on Ban dwidt h 11 . Return the r esolutio[...]
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Pagina 55
Chapter 1 55 Making B asic Measurements Making Noise Measurements Figure 1-46 Noise Marker in Signal Skirt 13. Set the analyzer to zero span at the marker fr equency by p ressing Mk r → , Mkr → CF , SP AN , Zer o Sp a n , Ma rke r . Note that the m arker amplitude v alue i s now corr ect sinc e all points a veraged a re at the same fr equency a[...]
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Pagina 56
56 Ch a pt er 1 Making Basic M easurements Making No ise Measurements Noise Measurement Example 2: The Normal m arker can also be u sed to make a s ingle freq uency measurement as desc ribed in t he pre vious example , again using vi deo filt e r in g or av er ag ing to obt a in a re a so n abl y sta bl e m easu r eme n t. Wh ile v ideo av e ra gi [...]
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Pagina 57
Chapter 1 57 Making B asic Measurements Making Noise Measurements 10. Measure the power b etween m arkers by pressing Marker , Mo re , Func tion , Band Powe r . The analy zer displays t he total power between the ma rkers. Se e Fi gur e 1- 48 . 11 . Add a discrete tone to see t he eff ects of the rea ding. T urn on the inter nal 50 M Hz amplitude r[...]
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Pagina 58
58 Ch a pt er 1 Making Basic M easurements Making No ise Measurements Figure 1 -49 Measuring t he Power in the Span[...]
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Pagina 59
Chapter 1 59 Making B asic Measurements Demodulating AM Signal s (Using the Analyzer As a Fixed T uned R eceiver ) Demodulat ing AM Sign als (Using the Ana lyzer As a Fixed T uned Recei ver) The zero sp an mode c an be used to r ecover amplit ude modulation on a carr ie r si gn a l. Th e an a lyz er op erat e s as a fix e d-t u n e d re ce i ver i [...]
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Pagina 60
60 Ch a pt er 1 Making Basic M easurements Demodulat ing AM S ignals ( Using the An alyzer As a Fix ed T uned Receiver) b. RF Output Power – 10 dB m c. AM On d. AM Rate 1 kHz e. AM Depth 80% 2. Set the a nalyzer a s foll ows: a. Pre ss Preset , F actory Pre set (if present). b. Set the c enter frequenc y to 300 MHz by pressi ng FREQUENCY , Center[...]
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Pagina 61
Chapter 1 61 Making B asic Measurements Demodulating AM Signal s (Using the Analyzer As a Fixed T uned R eceiver ) 6. Selec t zero sp an by ei ther pre ssing SP A N , 0, Hz ; or pressing SP AN , Zer o Span . See Fi gur e 1 -51 . 7. Change the sweep time to 5 m s by pre ssing Sweep , Sweep Time (M an ), 5, ms . 8. Sinc e the modulati on i s a st ead[...]
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Pagina 62
62 Ch a pt er 1 Making Basic M easurements Demodulat ing AM S ignals ( Using the An alyzer As a Fix ed T uned Receiver) Figure 1 -52 Measuring Modulation In Zero Span Figure 1 -53 Measuring Modulation In Zero Span 9. Use markers and d elta markers to measure the ti me par ameters of the wavef orm. a. Pre ss Marker and center the marker on a peak u [...]
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Pagina 63
Chapter 1 63 Making B asic Measurements Demodulating AM Signal s (Using the Analyzer As a Fixed T uned R eceiver ) Figure 1-54 Measuring Ti me Parameters 10. Y ou can t u rn yo u r an al yze r i nto a % A M in d ica t o r as fo l lows : a. Set tri gger to f ree run b y pres sing Tr i g , Free Run . b. Set the sweep t ime to 5 seconds by pres sing S[...]
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Pagina 64
64 Ch a pt er 1 Making Basic M easurements Demodulat ing AM S ignals ( Using the An alyzer As a Fix ed T uned Receiver) Figure 1 -55 Continuous Demodul ation of an AM Signal[...]
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Pagina 65
Chapter 1 65 Making B asic Measurements Demodul ating F M Sign als Demodulat ing FM S ignals As with amplit ude mod u lation (see page 59 ) y ou can utilize zer o span to demodulate an F M signal. How ever , unlike t he AM case, you cannot simply t une to the c arrier f req uency and widen the resol ution bandwidth. Th e reason i s that t he env el[...]
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Pagina 66
66 Ch a pt er 1 Making Basic M easurements Demodu lating FM Si gnal s 4. Set the spa n to 1 MH z by pre ssing SP AN , Sp an , 1, MHz . 5. Se t th e Y -A x is Un it s t o dB m by p re s s in g AMPLIT UDE , Mo re, Y -Axi s Units, dBm . 6. Set the reference leve l to – 20 dB m b y pre ssing AMPLITUDE , Ref Leve l , – 20, dB m . 7. Set the r esolut[...]
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Pagina 67
Chapter 1 67 Making B asic Measurements Demodul ating F M Sign als Figure 1-57 Determi ning the Offset De mo dula te the F M Sig n a l 1. Connect an antenna to the a nalyzer INPUT . 2. Perform a fact ory preset by pressi ng Pre set , Factory Prese t (i f pres ent). 3. T une the anal yzer to a peak the peak of one of you r local FM broa dcast sig na[...]
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Pagina 68
68 Ch a pt er 1 Making Basic M easurements Demodu lating FM Si gnal s 12. A c tivat e sin g le swe e p b y pr essing Single . See Fi gur e 1 - 58 . Figure 1 -58 Demodulating a B roadcast Si gnal[...]
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Pagina 69
69 2 Maki ng Comple x Mea sur eme nts[...]
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Pagina 70
70 Ch a pt er 2 Making Complex Measurements What’ s in This Chapter What’ s in T his Chapte r Thi s ch ap ter p ro vi d e s in f o rm atio n fo r m aki ng co m pl ex me a sure m e n t s. The pro cedures c overed i n this c hapter are listed below . • “ Making Stimulus Res ponse Meas urements ” on p age 71 . • “ Ma kin g a R efle c tio[...]
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Pagina 71
Chapter 2 71 Making Comple x Measurements Making St im ulus Respo nse Measurements M aki ng S tim ulus R es p on se M ea s ur em en ts What Are Stimulus Re sponse Measureme nts? Stimulus response measurements requi re a so urce to sti mulate a device under tes t (DUT), a receiver to analyze the f requency resp onse characteristi cs of the DUT , and[...]
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Pagina 72
72 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements Figure 2-1 T ransmission Measurement T est Setup 2. Perf orm a f actory preset by pressing Preset , Factory Preset ( i f p r es en t ) . 3. Se t the Y -A x is U n it s to dB m by pre ss in g AMPLIT UDE , Mo re, Y -Axi s Units, dBm . 4. Sinc e we ar e only i nterest[...]
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Pagina 73
Chapter 2 73 Making Comple x Measurements Making St im ulus Respo nse Measurements Figure 2 -2 T r ac king Generator Ou tput Power Activat ed 7. Put the sweep ti me of the a nalyz er into s timulus res ponse a uto coupl ed mo de by pre ss ing S weep , Swp Couplin g (SR). Auto coupl ed sweep times a re us u al ly mu ch fa ster fo r st im u lus res p[...]
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Pagina 74
74 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements Figure 2-3 Decrease the Resolution Bandwidth to Improve S ensitivity 10. Y ou mig h t not ic e a de crea se in the di spl aye d am plit ud e as t h e resoluti on bandwidth i s decrea sed, ( if th e analyzer i s an E7402A, E74 03 A, E 740 4A, o r E7 405A ) . T hi s [...]
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Pagina 75
Chapter 2 75 Making Comple x Measurements Making St im ulus Respo nse Measurements 12.Reconnect the D UT to the analyzer . Note tha t th e units of the re fe re nce lev e l h av e c hang ed to dB, indi ca ti ng t hat t his is no w a rel ative measurement. Pre ss T race/View , More, N ormal ize, Norm Ref Posn to change t he normalized ref erence pos[...]
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Pagina 76
76 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements T r acking Generator Unleveled Cond ition When using the trac king generator , the m e ssage TG unleve led may ap pe ar . Th e TG unl eve led mess age indica tes that the tracking gene ra to r so u rce po w er ( Source , Ampli tude ) c ould not be maintai ned at th[...]
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Pagina 77
Chapter 2 77 Making Comple x Measurements Making St im ulus Respo nse Measurements Measurements ar e made conti nuously , updating at the end of each swe e p. Thi s allows y ou to ma ke adj ust m ents a n d se e ch an g e s as t h ey happen. The si ngle s weep mode can also be used, p roviding time to stud y o r reco r d the da ta. The N dB band wi[...]
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Pagina 78
78 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements NOTE T o reduc e rip ple s cau sed by so urce r etur n lo ss, use 10 dB (E 7401A ) o r 8 dB (a ll ot her model s) or greater tr acking g enerator output attenua tion. T r acking generat or output a ttenuati on is nor mally a f unction of the sourc e power sel ected[...]
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Pagina 79
Chapter 2 79 Making Comple x Measurements Making St im ulus Respo nse Measurements 1 1. The knob or the data entr y ke ys can be u sed to c hange the N dB value f rom − 3 dB to − 60 dB to m easure the 60 dB bandwid th of the fi lter . See Figu re 2 - 7 . Figure 2- 7 N dB Bandwidth Measurement at – 60 dB 12.Pr ess N d B Points (Off) to turn th[...]
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Pagina 80
80 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements Figure 2-8 T ransmission Measurement T est Setup 2. Perf orm a f actory preset by pressing Preset , Factory Preset (if present). 3. Se t the Y -A x is U n it s to dB m by pre ss in g AMPLIT UDE , Mo re, Y -Axi s Units, dBm . 4. Se t the st ar t fre qu e n cy to 1 0[...]
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Pagina 81
Chapter 2 81 Making Comple x Measurements Making St im ulus Respo nse Measurements Figure 2- 9 T racking Generat or Output Power Activated in Log S weep 10.Put the sweep ti me of the a nalyzer i nto stimulus res ponse aut o coupl ed mo de by pre ss ing S weep , then Swp Co up ling (SR) . See Figu r e 2-9 . Auto coupled sweep t imes are usua lly muc[...]
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Pagina 82
82 Ch a pt er 2 Making Complex Measurements Making St im ulus Respo nse Measurements Figure 2-10 Normalized T race After Reconnecting DUT 14. Pre ss Ma rk er , De lt a Pa ir (R e f ), 10, MHz to p la ce the reference marker at the spec ifi ed cutoff freq uency . 15. Pre ss Delta P air (∆) , 2 0, MHz to p lace the s econd mar ker at the 20 MHz poi[...]
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Pagina 83
Chapter 2 83 Making Comple x Measurements Making St im ulus Respo nse Measurements Figure 2 -12 Minimum Stop Band At tenuation[...]
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Pagina 84
84 Ch a pt er 2 Making Complex Measurements Making a R eflection Calib ration M easurement Making a Reflec tion Calib ration Measurem ent The calibra tion standard for reflec tion measurements is usually a short circu i t conn e ct e d a t the re fe re n ce pl ane (t h e po in t at wh ic h the de v ice under tes t (DUT) will b e connected .) Se e F[...]
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Pagina 85
Chapter 2 85 Making Comple x Measurements Making a Reflect ion C alibrati on Measurement Reflection Calibration 1 . C o n n e ct the DU T t o th e di rect ion a l br id g e or c o u ple r a s s h o wn in Figu r e 2-13 . T ermina te the unc onnected p ort of the D UT . NO TE If possibl e, use a co u pl er or br idg e wi th t h e co rre ct t e st po [...]
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Pagina 86
86 Ch a pt er 2 Making Complex Measurements Making a R eflection Calib ration M easurement Figure 2-14 Sh or t Circuit Normal ized Measuring the Return Loss 1. Aft er calibrat ing the system with the above proc edure, reconnect the filter in pla ce of the s hort circui t without c hanging a ny analyzer setting s. 2. Use the marker to rea d return l[...]
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Pagina 87
Chapter 2 87 Making Comple x Measurements Making a Reflect ion C alibrati on Measurement Co nvert ing Retur n Los s to VSW R Re tur n l oss ca n be ex pr es s ed as a volt age s tan d in g w av e r at io (V SW R) value us ing the fol lowi ng table o r formula : Where: RL i s the measur ed return loss val ue. VS WR is so me time s state d as a rat i[...]
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Pagina 88
88 Ch a pt er 2 Making Complex Measurements Demodu lat ing and Listeni ng to an AM Signal Demodulati ng and List ening t o an AM S ignal The func tions listed in the menu und er Det/Demod allow y ou to de mod ul at e an d he ar si gna l inf or mat ion di spla yed on t he a nal yze r . Simpl y place a marker o n a signal of i nterest, a ctiv ate AM [...]
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Pagina 89
Chapter 2 89 Making Comple x Measurements Demodulat ing and Listeni ng to an AM Signal 7. Th e si gna l is dem o du la t e d at the m ark er po siti on o n ly for t h e duration of the demod time . Use the step keys, knob, or numeric keypad to c hange the d well tim e. F or example, press the s tep up key ( ↑ ) t o increa se the dwe ll time t o 2[...]
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Pagina 90
90 Ch a pt er 2 Making Complex Measurements Demodu lat ing and Listeni ng to an AM Signal 1 1. P ress Det/Demo d , Detector , Samp le t o set t he detec tor mode of the ana ly ze r to S ampl e. 12. Pre ss Det/Demod , Demo d , AM . Use the f ront pane l vol ume knob to co ntro l th e s peak er vo lum e. 13.Y o u can turn your analyzer into a % AM in[...]
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Pagina 91
Chapter 2 91 Making Comple x Measurements Demodulat ing and Listeni ng to an AM Signal Figure 2- 17 Continuous Demodulati on of an AM Signal[...]
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Pagina 92
92 Ch a pt er 2 Making Complex Measurements Demodu lat ing and Listeni ng to an AM Signal[...]