RSRC LVARLBVW,  ">>"@  J B&*">>"`PP``LL`440<ψȈfofofo     P\ P_\ _U U++++++++++++++++++++++++++++++++++++++++++++++++AӤ{UIHӤikՀ1A1II(Ii11(q|A(a|A(qqKqA AyAy yU1UIII1A"1"1"I>II199ݽwp1 1`p     QUQQ@  @ `@$ B B  aUUQV TKDM5010.vi2432 Trigger.viTek FG 5010.vi&Frequency_Response_Using_dm5010_dmm.viLInstrUseInstrUseInstrUseInstrUse++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ TKDM5010.vi2432 Trigger.viTek FG 5010.vi)&Frequency_Response_Using_dm5010_dmm.vi@  @ measurement"@trigger mode (0: continuous)@range (0: autorange)@ Instr. ID@function (0: DCV)@@`  @ pretrig pts@ # events@ Dly time@0 GPIB address@delay mode (delay off:0)@trig mode (auto:2)\@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts)trigger B (delay)T@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts) trigger A&& @function (0:sine)@ freq (Hz)@ ampl (volts)@ offset (volts)@mode (4:continuous) @!AM (F)@FM/VCF (0:off)@!complement (F)@!trigger slope (F:neg)@number of bursts@ phase (deg) @sym (%)@! output (T)Measures DC volts, AC volts, ohms, or ACV+DCV. Low frequency response and average readings are available. Diode test and Null function are not implemented. version a.0Trigger Setup: The "Trigger Mode" switch sets the mode for triggering the scope. 'Auto' trigger is used with repetitive waveforms and the trigger circuit auto-levels itself to the waveform. If it is desired to have the scope trigger at a certain level, the trigger mode should be set to 'Normal' and the desired voltage level is entered in the "Level" input. Non-repetitive and externally triggered single waveforms can be captured using the 'Single' trigger mode setting. The "Source" and "Slope" inputs set the source and slope for the trigger. The trigger function inputs on the front panel of the 'Tek 2432' VI set up the "A Trigger". A second trigger ("B Trigger") can be used to achieve a delayed trigger. Figure B-2 on page B-10 of the Operators Manual shows the delay modes available with the 2432. The six settings on the "Delay Mode" switch ('Tek 2432 Trigger' VI) correspond to the delay modes shown on page B-10. All the delay modes, except the first (delay off), should use the 'Single' trigger mode. When using the delay functions, the scope first receives trigger "A", delays by a specified number of events and/or amount of time, waits for an optional "B" trigger, and then acquires the waveform. The delay modes are described as follows: Delay Off: The waveform is acquired at the "A sec/div" ('Tek 2432 Channel' VI) sweep rate. The triggering of the waveform depends on the "Trigger Mode" setting and by the "Trigger A" parameter settings. The time value entered in the "Time of First Sample (Xo)" input determines the number of pretrigger points taken. Negative time values (time before the trigger) can cause up to 992 pretrigger points to be taken. Positive time values (time after the trigger) will put the scope in the "Time Delay;B, Run" mode. Event Delay; A: The waveform is acquired at the "A sec/div" sweep rate. The scope is first triggered with an "A" trigger. Acquisition is then delayed by a specified number of "B" triggers (events), as defined by the "# Events" input. The "Pretrig Pts" value determines the number of points returned before the last "B" event was received. Time Delay; B, Run: The waveform is acquired at the "B sec/div" sweep rate. After the "A" trigger is received, the acquisition is delayed by a specified time delay, as defined by the "Dly Time" input. The "B" trigger mode is set to 'Run' (Runs After) which means that acquisition will take place immediately following the delay and no "B" trigger is actually needed. The pretrigger points determines the number of points taken before the end of the delay time. A positive time value entered in the "Time of First Sample (Xo)" input sets the pretrigger points to 32 (minimum pretrigger value) and also sets the "Dly Time" value. Time Delay; B, Trig: This mode operates the same as the 'Time Delay; B, Run' mode except that a "B" trigger is required for acquisition following the time delay. The pretrigger points are referenced to the "B" trigger. Event Delay; B, Run: The waveform is acquired at the "B sec/div" sweep rate. After the "A" trigger is received, acquisition is delayed by the specified number of "B" events and the specified delay time. Acquisition takes place immediately following the delay time. The pretrigger points are referenced to the end of the delay. Event Delay; B, Trig: This mode operates the same as the 'Event Delay; B, Run' mode except that a "B" trigger is required for acquisition following the time delay. The pretrigger points are referenced to the "B" trigger. The "Pretrig Pts" can range from a minimum of 32 to a maximum of 992 in steps of 32. The "# Events" value can range from 1 to 65535. The minimum delay time equals 1/25 * "B sec/div" for sweep rates equal to or slower than 500nS or 1/50 * "B sec/div" for sweep rates of 200nS or faster. The maximum delay is 1.31mS for sweep rates of 500nS or faster, other maximums are listed in table B-10 of the Operators Manual. The delay resolution minimum is 20nS for "B" sweep rates of 500nS or faster. For sweep rates slower than 500nS the delay resolution becomes .04 * "B sec/div". The "Time of First Sample (Xo) specifies the time of the first sample (in seconds) with reference to the "A" trigger time. Negative values setup the "Pretrig Pts" value and set the delay mode off. The maximum negative time is 20 * "A" sec/div. Positive values set the delay mode to "Time Delay;B, Run" and set the "Dly Time" value. The maximum time entered should be limited to the maximum delay value. This Virtual Instrument can be used to control the Tektronix FG 5010 function generator in several different modes, including phase lock, burst, and gate modes. version a.0.LX? Z?*몪說着ꪯꫫ*ꪪꫪ着**ꪪ誫Ȍ  130000M 0000(0000(0000(?#"1`p`fDfgDdf!FdffFdfqfDffFdfafDf@D@Dffffffffffffffffffffffffffffffffffffbffffffffffffff? ??x{O8~><???q=q|y>?ϟy?<ǟ?xG珟w?@???:????й ;LFR OFF;;LFR ON;RQS ON;OPC ON;DIG 4.5;DCV ACV OHMS ACD 0 .200 2 20 200 1000MODE RUN;SEN MODE TRIG;SEN 0 .200 2 20 200 7000 2E2 2E3 2E4 2E5 2E6 2E70 .200 2 20 200 700AVG %d; CALC AVE; CALC OFF;RBRQS OFF; MODE RUN16%d,8< ,: 8L Pl\^H@8<@@^@*D@*D@*D@*Dt@*D$@@ Z0,>:6684@ <VIDS TKDM5010.vi(c%ux86% { code p(EwD{ E\EPPUEd$==0Ð,Ӏ}ELXC${(PRf:fZXCC,{0PRffZXC<{@PRZXC4}#E$EEƅ,ƅ ƅƅɍHƅhhUEPuEhxQRP$ S$d$ZY=sƅfxbƅ 6<Ƌ?ڋ=9-QRRP$hh8&d$ZY=T)ڃQRSP@$VQ/d$ ZY؃QRRP@$W(/d$ ZY?ڋ=9-QRRP$hh8&d$ZY=5T)ڃQRSP@$V.d$ ZY؃QRRP@$Wb.d$ ZYƅ fxEhxɍ4HHH Hƅ0hhUEP##"$$ %L%% { T # 4!"x#|!!##n!"V" d>#B*Z L "q%y%%%%%%W 7zZ[s)C]w-Gak1NCODE ׬p((`q7.0b71Oldest compatible LabVIEW.`Pcxc|pPPP"@trigger mode (0: continuous) @ average@ measurement@range (0: autorange)@! low freq resp@function (0: DCV)@ Instr. ID NI.LV.ALL.VILastSavedTarget0UnixNI.LV.ALL.goodSyntaxTargets&@0UnixMeasures DC volts, AC volts, ohms, or ACV+DCV. Low frequency response and average readings are available. Diode test and Null function are not implemented. version a.0%.6e%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0f%.0fQUQQ@  @ `@$ B B  aUUQ0DTHPD [88(/~@ measurement @ average&@function (0: DCV)*@range (0: autorange)2"@trigger mode (0: continuous)"@! low freq resp&@0 output stringF6@P @!status @code@0sourceerror IO0!@!selector@ Instr. ID.@timeout ms (488.2 global)$@poll response byteF6@P @!status @code@0source error out&@@!statusF6@P @!status @code@0sourceerror in$@0address string@mode (0)@ byte count@0data $@offset past number2"@!use system decimal point (T)&@0 Format String$$<<``@@@@@@@@@@<@@@`@@@@@`@@T@`@@@@d@@@@$T`@@d@@@@@@@$TTTT@@0@@@@TTT00`TT D@@tt@@ TDɵon offWDERER measurementSDaverage]D_3`3function (0: DCV)HW5)a6)aH`!`-!a-`D).~*.~range (0: autorange)hDmȐntrigger mode (0: continuous)Hh`YDХ  low freq respHDaKRWlKSWlDyyHHH Copyright 1993 National Instruments Corporation. All Rights Reserved.HDx_COPCOPHD]Y֌Z֌UD   Instr. IDH[VbVcгHa==H]!-!.H@`g)uh*uHd_HX]*+³HD^XHdXIdHDazKpzLpHD ^IaIaHD_rrHDbݺ$޺$HD`d d8Xh8YhIIISet RQS on operation complete; set to slow reading rate (more accurate)a# $ Build command string HDbHDbHDb##HDb2b2bHD _ԐHDc͑HDbЏHDbΑv""***Complete command string and send it to DMMHDbwNwOHDb4@4@HDb6BV6BVHDbKWTKWT|x@ 642|8  0 :H0;RW< 2h _.]@ 2h AV']p5p5l9@ 2h 'V0]o6o6k:0 h ]00 $,  |H XP t@ r4 FH(/@ 2 A+#2p5p5l9@ 2 #+,2o6o6k:0  2,d0 $4 H H XP NP $p H0oL|]"oL|]"oL|]4 F lp  0""@ 6 8֜ܣ0  У@ 6 4  < 2`  `@ 2` Av}p5p5l9@ 2` v}o6o6k:0 ` }0 $ , |4 G0$ Pl |8, h 8 L0 2$(QmRr ;0 2$-or :4  6$JQXm0 2T(IQJV 94 $zXLD| |7PW AV0@d0 2T-SV 84  6TBPQ0 2 (Ѝђ 70 2 - 64  6 X׍a; $i 1; $i PW HA+,dlPW Avt @P -d|,|NT4 F  0  -@ 2 @$p5p5l90$>H@ 2 $-o6o6k:, 4 t <   t4l 4   t~$ =aa_ 3J] ~ȆDa; $i 1; $i ,4t ; $i 1; $i 1; $i 1; $i =L|8 2 Uc,P80Measurement in volts or ohms8 2 > L8hBL : Wc0J0J/K.L-ML : 0J0J/K.L-M8hB8hB,LN measurements will be made and averaged. The average value is read. If Low Freq Resp is also active, the number of measurements is 4 times the value of N. dNAC+DC - measures and displays true RMS AC voltage elevated to DC voltage level8Jh  .,h  D< 8hX0p$D@277r77r8 hHB<   lTh,  , l8 hhB Select appropriate range for measurement. If autorange is selected, correct range will be determined, beginning at the highest range setting. 8 J f*v8"hBD"@2H3V3V 8#h B<# \`  p @ D#@2 NגLdbNג$iContinuous - internal trigger at slow reading rate Single Trigger - one measurement triggered 8$h`B<$O D`$KIf on, instrument computes the average of four ACV or ACV+DCV measurements.8$hB8$J`  8& 2 +$(8(hBL( : *0J0J/K.L-M BDHP TKDM5010.viH@ BDHPTH[8@Hh~G4(/Dx,( `"0& .,( T,RO(S0(S(0(@:40ePupm``4( B0WGe0)@*tjTztrd4) ByJq0*@?Td\(4* BHb0+@ t\>^N4+ B\s,N0,@+ ԓ4, Bܻ%0-@ 8.N>h4- B8eL.) M|? 5L,. xw0.M@,. ,0.$@eum.0.DL,. .40.L,. NL 9.h0.dO,.Dd,. :H, .=d=:.d-0.M4.+H);6H/A .B t, .@(t, .@4t, .@t,,.(t .@dt,.0.*` .BPX .B-PX .B44PX .B:PX,. @ .Bd=PX .@@OPX4. 7Wi4/ "!  0@ T 4,0 A0 40 2A T01 A 1 4 1@  1@D T 4,1 A 1D-.L41 2A P02 A 2 4,2 B,2 `42 2B, $ L03 B, % 3 43x\e0 3@l 4 ,3 "B` 3D'Dl43 2B` 1cH04 B` 0d4 4J`4,4Hh$h04 0,4Hkkd 04 \,4Hoo8 04 ,4Hssp04D ,4 0 D04.H|%z~ 4 \ 4  4 4p,4<\ 4@H?04-Hxz~ 4B \\ 4B D\ 4B|\ 4BpD\,48X 4@@H\04-Ht&w{ 4B \4z< 4B 0z< 4Bz< 4Bpz<,44T 4@@Hz<04-H 4B \,4 4B x<,4d< 4B,4<84 4Bpx,4<L,4d\XT 4@@H@L,4L 4@ \x,4 \\*B444 2B 805 B 545 0iTb045 pt]p045 0h@`40 5@.p45 0iZ0 5-=545 0i,5,B 5D(D,54x05%@3vFV~N 5@ d,5 (1B545 2B <06 B 6d46 lc46 ki0646 l8_046yD[L!46 lthp0,60xD 6@,6`7C0 6DE46 2C0 @07 C0 747 pD܍!) >@.4D)),>.+,W),@>P)̝ݔTX4>D800!0> 3) ̝4>D "4>D܅l0+4>D+p$>G>) >@.1+h+H,>.,Y+04>DX|#4>DHH0 @>P+hWgޓ,Z0> 3+ Wg4>D}0&>+HL>-+,l*(+**t*(d)P(('4>D- 4> #?-,? @0 /44?/2?280?-4?0D  ?DE4?/-.Xx Nm?/x/. ?.13L+H ?.3/0#$4?0./d\hsmm?/ ?.2//x4?0./_^shm?/x,?.! .0HxrDhHB?4B  2Dh 5C00C Dh 4DC=CNQ4CQTWgUCzemi C$|9$??4C0$|@$tmuqC@8 C$|?@84C0$|@OUueC@ C$|@X@4C0$|@U`ZCA C$|9@A4C-A\!4C0 C 3 #$,C#$Ax/4CQ Tp4CQ T}|4CQ % |~`4CQ 40dsth#4CQX`+4CQuJ̑X-4CQi8f24CQlk84CQpXp$=4CQ%2B̂Q4CQ%4DXTS4CQ&IYV,U4CQp04E  2> Xf,0F > Wg4F J> IeW G@TXTS,G=NTNS,GП><,GSNMNT=4GTY0GSPG~ >bH[Xuΰ`aU; i 1; i ,GSSSPV@; i 1; i 1; i 1; i =tHHLU|UUV8VhV8Gh>BGPW(8GhPBG>>HX(GeGDefault address of this device is 16. The address may be altered by setting the switches on the rear of the instrument from 0 to 30.8GhDhBG,ftG+&& G]PeggG9^^ZZGTX_~_G4{G>^>^GD^G{ Gff]PGŬG@  ^^GgG^^GGGGN~NGgGGxGD~G|~GD~ Gfg,G #A#ppn/A8GhBBG4G/ 0Y(|4G0fH`|4G0fW|K|4G0f^@| Gfxg`4G0fb8?| Gf4gG \fGfG]PGmЬG0{GeGiGg Gmn8k ktGg8GhBBGx4G/ ip|4G0jj(|Gk Gjjd4G0jk`'|Gkt Gj0k,G jGjdGm<GGn8G0lGdk GnnoHoGkt8GhC0BG{GnGn4G0jh\| Gjxmm4G0jn$)|Gn8 GjDm4G0qmt| GqnXn4G0qm0| Gq|n4G0qo4/|GoH Gqo4G0qo.|Go GqohGqGqGnGG8nGpGoH GrrrsPG4o8GhCdBGx4G/Dp|4G/ lT| Gqxwr4G0qrl6|Gr GqDr84G0qr5|Gr Gqrd4G0qs<4|GsP GqsGpqGqdGrG tGXrGt,Gdr Gu vt,GTsPlGVACV - AC Volts mode, DCV - DC Volts mode, OHMS - Resistance measurement mode, ACDC - 8GhB`BGHHss{=4G/uVvz$Gt,vvw\w4G0usfvnz4G0uvx;Vf^zGv GuvD84G0uv:Vf^zGv Guv 44G0qwH|Gr GuD}4 44G0uw$Vf^zGw Gu@w|L,G{THuLG {TuH  8\ 4 4 Gt, Gz<{|X|G"2"2G8vGz|G |X GlԄ<4G0X.>6|Gl G'$l4G0.&|G G+4G0(.&|G< G,l4G0.&|G G*\4,GF،`DLG`DF&L$tGl `G4G*L{{""&Gԃ G*P4G(Q+PUU+Q7PG<GG*:yHy:G44G/D,<\ z$G4 4G0X<\ Lz4G0NT\Xz G)PGp4G0 MLTPzG G(&4G0tLDLHzG G+ȉ@L4G0/>=y/A8O$Number of bytes expected from deviceLO :8 fr0J0J/K.L-M8Oh8B,O8ؖh8O05d 8Q$mode = 0 signifies terminate on EOI.LQ :5d 0J0J/K.L-M8Qh5dB,Q̗<58QhD4BQ9t:4~EhXE F Ft8yF G$@, Gp{ G8 H@HHI8 IJxJhp JĀK K\0}!K%K8 'L@X/)Lx*Lo+M$@,Mpl-M( .Nz/NT0N1OXP 2O0 3O@ 4P<} 5P6P` 7Q p 8Ql9Q`I:R4I;RpSd8?SȞ@T`AT` BU HCUh؛DU|EV %FVXh&GV&HW5JWPN LWJ NW8PX4RXXMTẌYY YIY YܐY숷 Y,Z Zt Z,yZLy{`W {ówOO8㟏x;x{;;?<=p?;wy'xv<xyy?<=?#?8|yy>qqx{;p?;wy'xv<xϟy?@???@???@???@???٩SGL, NOR, AUTOL,/SOU:CH1, SOU:CH2, SOU:LINE, SOU:EXT1, SOU:EXT2,*COU:AC, COU:LFR, COU:HFR, COU:DC, COU:NOI, %.;LEV:%.3eSLO:PLU, SLO:MINU,ATR MOD:SLO:PLU,*COU:AC, COU:LFR, COU:HFR, COU:DC, COU:NOI, ;BTR POS:%d, %SOU:CH1, SOU:CH2, SOU:EXT1, SOU:EXT2,@ SLO:MINU, %.;LEV:%.3e ,POS:%d;BTR RUN;;HOR MOD:ASW;DLYE MOD:OFF, ;HOR MOD:ASW;DLYE MOD:ON, ,MOD:RUNSA;HOR MOD:BSW;DLYE MOD:OFF, ,MOD:TRI;HOR MOD:BSW;DLYE MOD:OFF, ,MOD:RUNSA;HOR MOD:BSW;DLYE MOD:ON, ,MOD:TRI;HOR MOD:BSW;DLYE MOD:ON,%.;DLYT DLY1:%.3e;VAL:%d;, 8LH& Ph4@`\X8,: 8L@\ @8 @X zrjbZ|RxJ@ P@X @ &@ @ @  :   d @h @ "d @\ @ @| @t @l v H 2@ "  x p ` @P @H \` @\ @X @8 T B >L jD B< VIDS2432 Trigger.vi!2ux86|codet!Ew|E\EPPUEd$=g=xÐ,Ӏ}DELXC,H{0VWHBfffff_^C$P{(VWPfffff_^CLh{PVWh_^CT{XVWP_^C<\CDXC48C{ VWBfffff_^}E$EEƅ,ƅƅƅ4ƅƅƅƅ,ɍƅhhUEPƅ?6 QRP$VSQWR1d$ZY= ƅfxBkƅ ?6| QRPx$VSQWRn1d$ZY== ƅ fxF&ƅ x6t<Ƌ?ڋp=9-QRRPp$hh2Pm?P:@[P3!Pm_^ZY[]ÐVW@f_^Ul$SQRVW_^ZY[]Ð.Ul$SQRVWT$ QRPE@$Rcd$ZY=_^ZY[]ÐLQRu2{d$ZY,Ul$SQRVW}#QRU97d$ZY_^ZY[]ÐUl$SQRVWQRU7d$ZY_^ZY[]ÐUl$SQRVWuF FJFԚF$|F@FDQRhU6d$ZY_^ZY[]ÐXWIIUI@i/GQ    G I I2 q   7 `  GIG@G)R ""*## D"x|>tD~, \"Nfp6@HPX`h% #=Wq 'A[uCODEt׬8!(`q7.0b71Oldest compatible LabVIEW. aaaHHpBPP.P@ Dly time@ # events\@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts)trigger B (delay)T@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts) trigger A@delay mode (delay off:0)@trig mode (auto:2)@0 GPIB address@ pretrig ptsNI.LV.ALL.VILastSavedTarget0UnixNI.LV.ALL.goodSyntaxTargets&@0UnixTrigger Setup: The "Trigger Mode" switch sets the mode for triggering the scope. 'Auto' trigger is used with repetitive waveforms and the trigger circuit auto-levels itself to the waveform. If it is desired to have the scope trigger at a certain level, the trigger mode should be set to 'Normal' and the desired voltage level is entered in the "Level" input. Non-repetitive and externally triggered single waveforms can be captured using the 'Single' trigger mode setting. The "Source" and "Slope" inputs set the source and slope for the trigger. The trigger function inputs on the front panel of the 'Tek 2432' VI set up the "A Trigger". A second trigger ("B Trigger") can be used to achieve a delayed trigger. Figure B-2 on page B-10 of the Operators Manual shows the delay modes available with the 2432. The six settings on the "Delay Mode" switch ('Tek 2432 Trigger' VI) correspond to the delay modes shown on page B-10. All the delay modes, except the first (delay off), should use the 'Single' trigger mode. When using the delay functions, the scope first receives trigger "A", delays by a specified number of events and/or amount of time, waits for an optional "B" trigger, and then acquires the waveform. The delay modes are described as follows: Delay Off: The waveform is acquired at the "A sec/div" ('Tek 2432 Channel' VI) sweep rate. The triggering of the waveform depends on the "Trigger Mode" setting and by the "Trigger A" parameter settings. The time value entered in the "Time of First Sample (Xo)" input determines the number of pretrigger points taken. Negative time values (time before the trigger) can cause up to 992 pretrigger points to be taken. Positive time values (time after the trigger) will put the scope in the "Time Delay;B, Run" mode. Event Delay; A: The waveform is acquired at the "A sec/div" sweep rate. The scope is first triggered with an "A" trigger. Acquisition is then delayed by a specified number of "B" triggers (events), as defined by the "# Events" input. The "Pretrig Pts" value determines the number of points returned before the last "B" event was received. Time Delay; B, Run: The waveform is acquired at the "B sec/div" sweep rate. After the "A" trigger is received, the acquisition is delayed by a specified time delay, as defined by the "Dly Time" input. The "B" trigger mode is set to 'Run' (Runs After) which means that acquisition will take place immediately following the delay and no "B" trigger is actually needed. The pretrigger points determines the number of points taken before the end of the delay time. A positive time value entered in the "Time of First Sample (Xo)" input sets the pretrigger points to 32 (minimum pretrigger value) and also sets the "Dly Time" value. Time Delay; B, Trig: This mode operates the same as the 'Time Delay; B, Run' mode except that a "B" trigger is required for acquisition following the time delay. The pretrigger points are referenced to the "B" trigger. Event Delay; B, Run: The waveform is acquired at the "B sec/div" sweep rate. After the "A" trigger is received, acquisition is delayed by the specified number of "B" events and the specified delay time. Acquisition takes place immediately following the delay time. The pretrigger points are referenced to the end of the delay. Event Delay; B, Trig: This mode operates the same as the 'Event Delay; B, Run' mode except that a "B" trigger is required for acquisition following the time delay. The pretrigger points are referenced to the "B" trigger. The "Pretrig Pts" can range from a minimum of 32 to a maximum of 992 in steps of 32. The "# Events" value can range from 1 to 65535. The minimum delay time equals 1/25 * "B sec/div" for sweep rates equal to or slower than 500nS or 1/50 * "B sec/div" for sweep rates of 200nS or faster. The maximum delay is 1.31mS for sweep rates of 500nS or faster, other maximums are listed in table B-10 of the Operators Manual. The delay resolution minimum is 20nS for "B" sweep rates of 500nS or faster. For sweep rates slower than 500nS the delay resolution becomes .04 * "B sec/div". The "Time of First Sample (Xo) specifies the time of the first sample (in seconds) with reference to the "A" trigger time. Negative values setup the "Pretrig Pts" value and set the delay mode off. The maximum negative time is 20 * "A" sec/div. Positive values set the delay mode to "Time Delay;B, Run" and set the "Dly Time" value. The maximum time entered should be limited to the maximum delay value. %.0f%.0f%.2e%.0f%.0f%.0f%.0f%.3f%.2f%.0f%.0f%.2f%.3f%.0f%.0f%.2f%.2f%.2f%.0f%.0fAӤ{UIHӤikՀ1A1II(Ii11(q|A(a|A(qqKqA ApDTHPD [88ho~"@ level (volts)@ pretrig pts&@0 GPIB address@ # events@ Dly time.@delay mode (delay off:0)$@trig mode (auto:2) @!slope @source (ch1:0)h\@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts)trigger B (delay) @coupling (DC:3)`T@P@source (ch1:0)@coupling (DC:3) @!slope@ level (volts) trigger A&@0 output string0@!selector! F6@P @!status @code@0source error out&@@!status.@timeout ms (488.2 global)F6@P @!status @code@0sourceerror in@mode (0)@0data$@0address string44XXtt$$$$$$$8$$$$$$$$$$$$$$$T$$8$$8$d$$$8$$t$tddd$$$$$$$$$$$$$dd$$$X$$$$$t$$$$$$tt\x4Tt WDIVIV  pretrig ptsXD<=  GPIB addressH<`KyLyTD3@3@# eventsTD+ + Dly timedD i i delay mode (delay off:0)^D$C1$D1trig mode (auto:2)H`(T)TQDFeGeslopeH]![-!\-[Dcoupling (DC:3)UDupuq trigger AOD[b\b+ -YD level (volts)ZDGHsource (ch1:0)HLa<h=hHdXNzOz[Dcoupling (DC:3)HWᅶᳳ]Dvvtrigger B (delay)ODHOIO+ -YDpq level (volts)QD3R4RslopeH_׉׳ZD,-source (ch1:0)HD`!-F!-F HD_H=TkH>TkHD<]>[?[HD[ïHDX_HD@a/L0LH_IUIVȳH_3?3@ȳH^*+ȳH_Zh[ hH<_!-!.H_˳H_H _H_ u vHh]ݕޖ볳HH_n|o|HDL`jwvjxvHD4`HD$`iiuijuHD`rsHD` 8 8HD]amamHD`_JtKtHDtXbЮcЮ~((2"A TRIGGER" MODE, SOURCE, COUPLING, SLOPE & LEVEL.c[\"A TRIGGER" PARAMETERS.HDX,P,PHD^+g2+g2HD a:Gv{:Hv{HDaLMHD_2c3cHDa1i2iHD^?TK?UK T1 U1FSEND PRETRIGGER POINTS AS 'ATR POS' - AS 'BTR POS' WHEN IN DELAY MODE.cYZ"B TRIGGER" PARAMETERS.HD aFuFvHD`HD$aE*uaE+uaHDaHD(aݼHT`(@=5HTa.<@.F5t   (SELECT "A SWEEP" HORIZONTAL SWEEP MODE WHEN DELAY IS OFF OR "EVENT DLY;A" (ATR DELAYED BY B EVENTS) DELAY MODE IS SELECTED. THE "B TRIGGER" MODE: 'RUNSA' WILL FORCE A TRIGGER (RUN) IMMEDIATELY AFTER THE SPECIFIED DELAY OR #EVENTS. 'TRI' TRIGGER MODE WILL WAIT UNTIL TRIGGERED FOLLOWING THE DELAY.eC D SEND DELAY MODE & PARAMS.HD4aHD`HD8a\\HD`o{w]~@ 6@42w8~  P W @AQ02L< 2 p Z.`^@ 2 p AQ'Xp5p5l9@ 2 p 'Q0Xo6o6k:0  p X00 $0 @ |L< Sdt) 3X8!4 Ft4 F  tol0 7  "$0  ) 4  Zct@P 3584 F0  x@ 20 A p5p5l9 4XD WD WD WD WD W4 F F0 :t0$%t%< 2!4 ;i4]p P0ȼ"ȼೳ"ȼೳ0 :P0#l##p  0_y"_y"_y@ 6 8iq0  iq@ 6 4iq  PW AD}"J< 2 M{Y@ 2 ADKp5p5l9@ 2 DKo6o6k:0  K}HXP 6 l4 FP@ 2!4 A29p5p5l9@ 2!4 29o6o6k:@ 6P80 P@ 6P4Ҟ  PW PA5~< 2 Y@ 2 Ap5p5l9@ 2 o6o6k:0  , P4X00$0 4|%&&8<Su*7:0 !4 9k4 F u0 7 %0  *4 GP@Pk898 4 F o@ 2 Akrp5p5l9@ 2 kro6o6k:0  r&l&&4 G92SHXP;", 90C0C0C0C0C0 : 0Y^p t0"ֳ"ֳ@ 6t80 t@ 6t4Ơ  PW tA;< 2 ]@ 2 Ap5p5l9@ 2 o6o6k:0  , t9HXP+2 < |4 >AUTOTRIGGER IGNORES THE SPECIFIED TRIGGER LEVELS, "B TRIGGER" & DELAY FUNCTIONS. TRIGGER MODE SHOULD BE SET TO SINGLE TO USE THE DELAY FUNCTIONS.8>h B,>h3 8> 20 |,@p3538@h0B8@h pB<@O D f*(8@h4XB8@h B<@ | d5@4D@@2 =až=a,A7DL7|LA :0 0J0J/K.L-MXAC+/- 18 VOLTS, SPECIFIES THE TRIGGER VOLTAGE LEVEL FOR 'TRIGGER A'.8AhB8AhPB9Tj \D4<D4\ 29T 1d0] 9T .e] ]@,]@9r]<4] 29 0j0^ 9 -k^L^    ,^B9z ^D=<4^ 29 >SL0_ 9 =PM_4_`[LF(04_`\HT00_74_`^TO04_0D_ ,_4_`K`04_`tMP _ 4_`Zd0 8_60T4_`NdH $_<( _tHD0_7 4_`NN04_`O|V0_( _@,@t(0_7x_4_`VI4_`W\S$0 _@+<D0_74_`SRH0_ _@+4_`RT !0_7 _< _@(_P4_`T[|04_`Z4J 4_`WY0\_hpL@ t4_`^0 4_  S24` X4a/8Ya ,P a58p 4a0aP a@*L$ a@),a"Xh:,a]9 aD=4P0a 19 Aaa a@)|#,ax_@aPm_}jdTdBh%\h#T%!$l"t \8@ < 8@hP#t_,^s0h 3& h#T4h}T\!(4h'Ah \>4hu0y04h(Xg#h@?84hh|0/4h(w !h8 4h),`hP h<4hil04hmm04hny04hq`c@%4hn0-4hy}0 h@D3.d*4hih0.4hvX0+4hiXl '4hlp!&4h~4~l04hqa04hq04hrxtT0,4huul$4hxP0)4h,ܘ h#T 4hx *|h-,t,(,*,@, ++p*L'+)+<+**))|)H((t($''l4hC,0"4h  4i B  j@D6$0.D,jD.;4j 2; 0k ; k* k@D4d/0/,kD/;4k 2; 0l ; l/ l@D7(//,lD0;4l 2; ]0m ; ^m/4mD9,mD1l<04m 2<0 n|=0n <0 m}>n.D n@D511,nD284o|084ot0<4o404\o67(63x566X6$5558544d3304o7Co4o8B^8]q4oQ.dȁ4oQ/04oQ/^44oQ0m}>~P}p4oQ1DT|4o0D4o0Dd4o0D04o0D\4o0D 4o0D"~4o/>=]]}Ono>h>?84o0=>TCmXxMrno>h o='l> >h4o0=>McXmRhno> o='> \4o0=?$tCcMmHhno?8 o=($>oK|a@d; i 1; i o~t8X(]_6,~\`a@; i 1; i ooK; i 1; i 1; i 1; i =l??p@@@,A\AApo'UdudUhRho40(oo-(VV(To\FԬo7@@(AA(oL$o0@(@A(<oDxG o8YY(o\\O^8oh9B8oh9B8oh9TBodGDo8oh9 BoxGoǺ11oLx8oh8BoHĬooM8oh8BoI8oh8BoJ,oss4o/`MD)I{oK| oK, MdK|4o0K,@x)91{ oK,K X4o0K,Dw)91{ oK,K 4o0K,Hv)91{ oK,LDMo]D]>u4s/z$Dz$sx{4{||l4s0ztwN$D4z4s0ztxMh4s0zt{L4<8zs{ szt+p{T%4s0zt{K,40zs| szt+{!4s0zt|X6$,(zs|l szt-|$K|s12s6%f'%dfs>h{4ss*LQOQs%{s11>Ouii CC Iuyy[X[X`u EETTAu,u*ggZju*D[D[u(tddu'l@r@Mru5׬u4d4u0z-w72|ut (x  Ƃ  ƌ  Ɩ ƘD Helvetica Helvetica Helvetica00RSRC LVINLBVWR \ Q 4 LRSID X>8>4Pp6PI8Pp9P;PȸP@P AP BQpW DQ{FQ%HQ(M IQ4HN KQ@85LQL5NQXqQdsQp8uQ|Q R X Y؜ Yi Z8ZhZ  [4@-[P- \(n \L0 \ W \+]P+]p ^^` ^}_ p_X_`P7`h`X a at+ a} #b h+ &bl()b,c/cP2ck3c5d47d:dh=e?edر CeX Ee(|GfHh&JfN MfHOg,PgxQgXRhxI Sh\J ThJ UhVi@(J WiXJ XjYjxZjh[k\k\]k^k(_l@`lam$8bm8cm8dn$enp fn@goXJhoTJio jqKkqlqАmr nrh orpsPrsLtsȩ sn tLW thht t7tx!t|"uX+ $u%u$'u4( (uD@*uTP +ud8-ut`.up0uh1u;uudQ0%Q\PM2432 Trigger.vif-XUDTU*몪ꪪ着着ﯨ*+ꪪꫪ뫪 Ȍ  38h@x ```P````X ```x???"@!"@!"@!"@!"@!"@!"?g<=;~ss8>s?w|>s|x?wyy>??qx{;;>y=>08¸xyYO8㟏x;c?<;~q4pxϟ?x>xϟ?x3<'1g'q8¸#?ώ?;?ᨏ>ówO{;:wQ|gp?;w=g;?ᨏ>ówOO8㟏x;󟟏='>?~LVINTek FG 5010.vi&& @function (0:sine)@ freq (Hz)@ ampl (volts)@ offset (volts)@mode (4:continuous) @!AM (F)@FM/VCF (0:off)@!complement (F)@!trigger slope (F:neg)@number of bursts@ phase (deg) @sym (%)@! output (T) x xPe cL P d-` cbP"@P@flg@oRt@eofudfP!trigger slope (F:neg)x!dfdP!txdP!oldP!ext c XP"@P@flg@oRt@eofudfP! output (T)p!dfdP!txdP!oldP!ext P P P    P P   cZP"@P@flg@oRt@eofudfP ampl (volts)p dfdP txdP oldP ext P" P@@ c^P"@P@flg@oRt@eofudfPfunction (0:sine)xdfdPtxdPoldPext P`P"@P@flg@oRt@eofudfPmode (4:continuous)pdfdPtxdPoldPext c \P"@P@flg@oRt@eofudfP!complement (F)x!dfdP!txdP!oldP!ext P   cVP"@P@flg@oRt@eofudfP freq (Hz)p dfdP txdP oldP ext cTP"@P@flg@oRt@eofudf P!AM (F)x!dfdP!txdP!oldP!ext c\P"@P@flg@oRt@eofudfP offset (volts)x dfdP txdP oldP ext^P"@P@flg@oRt@eofudfPnumber of burstspdfdPtxdPoldPext P c\P"@P@flg@oRt@eofudfPFM/VCF (0:off)xdfdPtxdPoldPext cXP"@P@flg@oRt@eofudfP phase (deg)xdfdPtxdPoldPext cTP"@P@flg@oRt@eofudf Psym (%)pdfdPtxdPoldPext" P@@" P@@b P         @P b P         @P b P         @P  0 0(0 0 0 0 0 0 0( 0 0 0 0 0 0 0 0 0 0 0 0Z P$@P@0P c@0 output stringPmode (0)@0 output string@0 output string@0 output string@! output (T)@0 output string@!complement (F)@0 output string@!trigger slope (F:neg)0@FM/VCF (0:off) @!AM (F)@ phase (deg)@0 output string@number of bursts@0 output string @sym (%)@0 output string@ offset (volts)@0 output string@ ampl (volts)@0 output string@ freq (Hz)@mode (4:continuous)@0 output string@function (0:sine) ch c c< d P``` d dn t 7 n $ ld d 0 d ^ Z Z@'@@?@1-@ 2@???O@???$@???4 9MODE PHLOCK; MODE BURST; MODE GATE; MODE TRIG; MODE CONT;SINE; SQUARE; TRIANGLE; AMPL %.3e; OFFS %.3e; FREQ %.3e;PHA %d;NBUR %d;SYM %d;AM OFF;AM ON;FM ON;VCF OFF;FM OFF;VCF OFF;FM OFF;VCF ON; SLOPE POS; SLOPE NEG; COMP OFF;COMP ON;OUT ONOUT OFF25Z \D d0<> 2,,b8<h P\^$ p8 dpx4  >< L   T  ,^8<D  Hnf^@p @h jl  @\ ,@d X~v@< ~@L @T @D ` >X P H @  @4 V@8 n0 J($,D@<84@0@$ @, 0(  nnHVIDSTek FG 5010.vi#e ux86  code`e "Ew E\EPPUEd$==Ð,Ӏ}ELXC,\{0VW\fffff_^C$d{(VWdfffff_^PR=ZXCt,{xP,RZXCDh{HPhRf:fZXCl${pP$R]ZXCp{ PpRffZXCT8{XP8RZXCd4{hP4RtZX<P<RffZXLPLRffZXC4T{8VWTfffff_^C|DPDRf:fZX}E$EEƅƅƅ0ƅƅ,ƅPƅ ƅƅdƅƅƅƅ,ɍ|ƅxƅxfxƅ|ɍHƅ hhUEP"ƅ=0=9$QRRVhh2(d$ZY=v ??ϋ0=%QRRWP@$藣d$ ZYƅfxB}Ehx ɍHHƅ0hhUEPGd$ZY=*Dž E\EPQRP/d$ZYÐ. E\QRhPEP$P $Gd$ZY= Ð}v=ƅfxfF Ehxƅ|fx [ } }P}}+QRPE@$>Pd$ZY="= p h搐ÐEw  E\EPPUEd$===u=tEw Ew‰ppVL@'PUEd$=ÐPTHk P@C Pb }P\^ cP\W IPQ /PlL P[! Pk; PkU P=o P= P= yP2 _P EP +P|  P|% P8v? P8vY PDs  Ðx& Ðx& Ðx& Ðx& Ðx&gzp p @'PUEd$=ÐP#0 Pj WP P P  P9R oP  5PM  P  Pa : P t MPn   P= ! P $" P %\ eP & +P^ " P= #  P ' D }P1~ CP2 PO3 P4,  Pf  [P  !_^ZY[]ÐVW f_^Ul$SQRVW_^ZY[]Ð.Ul$SQRVWT$ QRPE@$R:Pd$ZY=_^ZY[]ÐZQRuhd$ZY,Ul$SQRVW}#QRU#d$ZY_^ZY[]ÐUl$SQRVWQRU貔#d$ZY_^ZY[]ÐUl$SQRVWu(! F ! F}! F! F$ F@! FDQRhUw#d$ZY_^ZY[]ÐXInI GG GG4GG , U      1   a'f0o5^>g-  "^"k##M"' N   ?Q_ GUw%=i/s { %_?^0Jd~4Nh$:PfCODE`e ׬`"(`q7.0b71Oldest compatible LabVIEW.\^^^p PPP @ ampl (volts)@ freq (Hz)@! output (T)@!trigger slope (F:neg)@mode (4:continuous)@!complement (F)@function (0:sine) @!AM (F)@FM/VCF (0:off)@ phase (deg) @sym (%)@ offset (volts)@number of bursts"  NI.LV.ALL.VILastSavedTarget0UnixNI.LV.ALL.goodSyntaxTargets&@0UnixThis Virtual Instrument can be used to control the Tektronix FG 5010 function generator in several different modes, including phase lock, burst, and gate modes. version a.0%.4f%.0f%.0f%.0f%.0f%.4f%.0f%.0f%.0f%.0f%.4f%.0f%.0fyAy yU1UIII1A"1"1"I>II1DTHPD [88x~8*@!trigger slope (F:neg)@! output (T)"@ ampl (volts)&@function (0:sine)$@mode (4:continuous) @!complement (F)@ freq (Hz) @!AM (F) @FM/VCF (0:off)@ phase (deg) @sym (%) @ offset (volts)&@number of bursts&@0 output string0@!selectorF6@P @!status @code@0source error out&@@!status.@timeout ms (488.2 global)F6@P @!status @code@0sourceerror in@mode (0)@0data$@0address stringL00LLll((DD\\|||lL(\DHl VD G G  modulationVD== parametersODImIm+ -yD9F39F3 trigger slope (F:neg)nD  output (T)WD  phase (deg)SD4_5_sym (%)ZDWdWdoffset (volts)\DW2dW3dnumber of burstsjDAM (F)XD+68+78  ampl (volts)]D+,,,function (0:sine)HT]1P=|1Q=|_D!"mode (4:continuous)HlYL΄M΄rDǎȎ complement (F)UD+8+8  freq (Hz)ZDmmFM/VCF (0:off)HD X'S(SHDd]cIHdY/6;D/7>was 24HD]2>2>sinesquaretriangle* phase lockburstgatetrig continuousoffFMVCF i\i` ^` dh fh  < @ >@FPHPTek FG 5010.vi2L@ FPHPW82D+2K0 : h0Pkpt4 d H4 d>4 dHn4 G 8G40d< 2   HmHm㳳Hm㳳HmHm|84 G!$0dT!0 !޳|@P--DD4 Fp @ 6p Ap5p5l9@ 6p o6o6k:0 p Ǧ@Ph2..J4 F 3`@ 6 A29p5p5l9@ 6 29o6o6k:0  9@PVw2$0P4 F Ve@ 6 Aenp5p5l9@ 6 nwo6o6k:0  ew@ PV1w1,1Xn,4 F V1e@ 6 Ae2n9p5p5l9@ 6 n2w9o6o6k:0  e9w, @ 4 G*Pl *Pೳ@ P *3K#$0t>4 F *59,@ 6 A93B:p5p5l9@ 6 B3K:o6o6k:0  9:K0 d L Z |4H XP *$%t @4 F h*-@ 8hP WHAV,| p  h0|`y"|`y"|`y@ 6 h8jq0  hOjq@ 6 h4CjIq  0 : 0t#y<  2 0O>}< X@ 2 A.F7Mp5p5l9@ 2 7F@Mo6o6k:0  .M@0d h |HXP 0&' $P4 F  Tp  0i"i肳"i肳@ 6 8*s0z0  s$z@ 6 4sz  0 >H0 D4L<  2X KυPW@ 2X ABIp5p5l9@ 2X BIo6o6k:0 X Iч0d ,b|4 G(Ə\0d(P  (ͯೳͯͯޏͯߏͯ|`@P4*KH+d(4 F *9d@ 6 A9Bp5p5l9@ 6 BKo6o6k:0  9K0ddD|0d*P|,0d0d,,^ |HXP<n-+8@D4 FHnp H00C8M"0C8M"0C8M@ 6H87D<L0 H C5M@ 6H4DL  0dHd |-|<  6 &T|X@ 6  A$p5p5l9@ 6  $o6o6k:0  $V0dLp> |50d|5L 4t, h|\0xh4, t ؤ0 ddz0 dDdz  4        , t   h  X"8hHB,P)*)0 2%(i\ja 0 2%-^a 4  6%b;p\40 2',(di 0 2',-fi 4  6',QdH0 2-( <!A 0 2-->A 4  2-*'<t4 dL}ZX!L@!7a@; di 1; di P!W hA.5@#TP!W A1ч(d!~d`e [|X]DȆDa; di 1; di !@!t2D; di 1; di 1; di 1; di =L|( X