ELEKTRONSKI FAKULTET Katedra za mikroelektroniku 1 ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe Univerzitet u Nišu Elektronski fakultet Katedra za mikroelektroniku ANALOGNA MIKROELEKTRONIKA (Semestar V, 2017. godina) PRATEĆI MATERIJAL ZA LABORATORIJSKE VEŽBE Danijel Danković
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ELEKTRONSKI FAKULTET Katedra za mikroelektroniku
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
Univerzitet u Nišu Elektronski fakultet
Katedra za mikroelektroniku
ANALOGNA MIKROELEKTRONIKA
(Semestar V, 2017. godina)
PRATEĆI MATERIJAL ZA LABORATORIJSKE VEŽBE
Danijel Danković
ELEKTRONSKI FAKULTET Katedra za mikroelektroniku
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
I. LM317
1. Create a new symbol (File->New Symbol...).
2. (File->Save as), name the symbol (for example “LM317”), and choose a safe place for it to be saved.
3. Now build the symbol shown in Fig. 1 (Draw->...). Fig.1
4. Add the pins as shown in Fig. 2 (Edit-> Add Pin/Port...). Fig.2
ELEKTRONSKI FAKULTET Katedra za mikroelektroniku
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5. Now define the attributes as shown in Fig. 3 (Edit->Attributes->Edit Attributes...).
6. Edit the visibility of attributes as shown in Fig. 4 (Edit->Attributes-> Attribute Window...).
Fig.3 Fig.4
7. Add text LM317 (Draw->Add text...) to your symbol.
8. Your symbol is shown in Fig. 5. Fig.5
ELEKTRONSKI FAKULTET Katedra za mikroelektroniku
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9. Edit SPICE Netlist so that it is the same as the one listed below, name it (“LM317.sub”) and choose a safe place for it to be saved. .SUBCKT LM317 in adj out * PEI 08/98 p62 J1 in out 4 JN Q2 5 5 6 QPL .1 Q3 5 8 9 QNL .2 Q4 8 5 7 QPL .1 Q5 81 8 out QNL .2 Q6 out 81 10 QPL .2 Q7 12 81 13 QNL .2 *Q8 10 5 11 QPL .2 Q8 10A 5 11 QPL .2 Q9 14 12 10 QPL .2 Q10 16 5 17 QPL .2 Q11 16 14 15 QNL .2 OFF Q12 out 20 16 QPL .2 Q13 in 19 20 QNL .2 Q14 19 5 18 QPL .2 Q15 out 21 19 QPL .2 Q16 21 22 16 QPL .2 Q17 21 out 24 QNL .2 Q18 22 22 16 QPL .2 Q19 22 out 241 QNL .2 Q20 out 25 16 QPL .2 Q21 25 26 out QNL .2 Q22A 35 35 in QPL .2 Q22B 16 35 in QPL .2 Q23 35 16 30 QNL .2 Q24A 27 40 29 QNL .2 Q24B 27 40 28 QNL .2 Q25 in 31 41 QNL 5 Q26 in 41 32 QNL 50 D1 out 4 DZ D2 33 in DZ D3 29 34 DZ R1 in 6 310 R2 in 7 310 R3 in 11 190 R4 in 17 82 R5 in 18 5.6K R6 4 8 100K R7 8 81 130 *R8 10 12 12.4K R8 10A 12 12.4K R9 9 out 180 R10 13 out 4.1K R11 14 out 5.8K R12 15 out 72 R13 20 out 5.1K R14 adj 24 12K R15 24 241 2.4K R16 16 25 6.7K R17 16 40 12K R18 30 41 130 R19 16 31 370 R20 26 27 13K R21 27 40 400 R22 out 41 160 R23 33 34 18K
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Linearni izvori napajanja”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 6. Fig.6
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
III. Linearni izvori napajanja-2
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Linearni izvori napajanja-2”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 7. Fig.7
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
IV. Linearni izvori napajanja-3
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Linearni izvori napajanja-3”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 8. Fig.8
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
V. DC/DC pretvarač LM317T
1. Realizovati DC/DC pretvarač.
2. Iza DC konektora postaviti diodu koja služi za zaštitu od suprotne polarizacije.
3. Napraviti DC/DC pretvarač sa promenljivim izlazom u opsegu napona od VOUTmin =3V do VOUTmax =9V (za ulazni napon VIN =12V). Izlaz podešavati trimerom Rp. Primer:
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
VI. DC/DC pretvarač LM350
1. Realizovati DC/DC pretvarač
2. Napraviti DC/DC pretvarač sa naponom na izlazu VOUT =5V (za ulazni napon VIN =12V). Izlaz podesiti trimerom Rp. Primer:
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
VII. DC/DC pretvarač TS1086
1. Realizovati DC/DC pretvarač
2. Napraviti DC/DC pretvarač sa naponom na izlazu VOUT =5V (za ulazni napon VIN =12V). Izlaz podesiti trimerom Rp. Primer:
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
VIII. DC/DC pretvarač LM317T
1. Realizovati DC/DC pretvarač.
2. Napraviti DC/DC pretvarač sa naponom na izlazu VOUT =7.5V (za ulazni napon VIN =12V). Izlaz podesiti trimerom Rp. Umesto trimera 2k koristiti rednu vezu trimera 1k i fiksnog otpornika 1k. Primer:
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
IX. Step-Down Switching Regulator - 1
1. Start the LTspice IV program (Start->All Programs-> LTspice IV).
2. Create a new schematic (File->New Schematic...).
3. (File->Save as), name the schematic (for example “Step-Down Switching Regulator LT1766”), and choose a safe place for it to be saved.
XIII. Step-Down Voltage Regulator – LM2596 SIMPLE SWITCHER - 1
1. Connect electrical elements on protoboard as shown in Figure 13.
2. Measure voltages DC INPUT and REGULATED OUTPUT. Fig.13
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XIV. Step-Down Voltage Regulator – LM2596 SIMPLE SWITCHER - 2
1. Connect electrical elements on protoboard as shown in Figure 14.
2. Measure voltages VIN and OUTPUT. Fig.14
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XV. Step-Down Voltage Regulator – LM2596 SIMPLE SWITCHER - 3
1. Connect electrical elements on protoboard as shown in Figure 15.
2. Measure voltages VIN and OUTPUT. Fig.15
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http://www.national.com/ds/LM/LM2596.pdf
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XVI. Inverting Amplifier
1. Start the LTspice IV program.
2. Create a new schematic (File->New Schematic...).
3. (File->Save as), name the schematic (for example “Inverting Amplifier”), and choose a safe place for it to be saved. Now build the circuit shown in Fig 16.
2. Create a new schematic (File->New Schematic...).
3. (File->Save as), name the schematic (for example “Non-Inverting Amplifier”), and choose a safe place for it to be saved. Now build the circuit shown in Fig 17.
2. Create a new schematic (File->New Schematic...).
3. (File->Save as), name the schematic (for example “Summing Amplifier”), and choose a safe place for it to be saved. Now build the circuit shown in Fig 18.
4. Run the LTspice IV simulation (Simulate->Run). Fig.18
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XIX. Invertujuća konfiguracija
1. Connect electrical elements on protoboard as shown in Figure 19.
2. Set channel 1. CH1: Sine waveform
1 kHz 2 V Amp 0 V offset
3. Measure voltage Vout ( VinR
RVout
1
2 ).
4. Change: V+ = 5 V, V- = -5 V, R1=1 kΩ Fig.19
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XX. Neinvertujuća konfiguracija
1. Connect electrical elements on protoboard as shown in Figure 20.
2. Set channel 1. CH1: Sine waveform
1 kHz 2 V Amp 0 V offset
3. Measure voltage Vout ( VinR
RVout
1
21 ).
4. Change: V+ = 5 V, V- = -5 V, R1=1 kΩ Fig.20
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXI. Sabirač
1. Connect electrical elements on protoboard as shown in Figure 21b.
2. Set channels 1 and 2. CH1: Square waveform CH2: Square waveform
1 kHz 1 kHz 1 V Amp 1.5 V Amp 0 V offset 0 V offset
3. Measure voltage V_out ( 213
1
2
1 V
R
RV
R
RoutV ).
Fig.21
Fig.21b
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXII. Sabirač_sa blokom za invertovanje napona
1. Connect electrical elements on protoboard as shown in Figure 22.
2. Set channels 1 and 2. CH1: Square waveform CH2: Square waveform
1 kHz 1 kHz 1 V Amp 1.5 V Amp 0 V offset 0 V offset
3. Measure voltage V_out ( 213
1
2
1 V
R
RV
R
RoutV ).
Fig.22
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXIII. Diferencijalni pojačavač
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Diferencijalni pojačavač”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 23. Fig.23
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXIV. Integrator
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Integrator”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 24. Fig.24
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXV. Integrator_2
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Integrator_2”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 25. Fig.25
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXVI. Diferencijator
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Diferencijator”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 26. Fig.26
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXVII. Diferencijalni pojačavač
1. Connect electrical elements on protoboard as shown in Figure 27.
2. Set channels 1 and 2. CH1: Sine CH2: Sine
1 kHz 1 kHz 1 Vpp Amp 500 mVpp Amp 0 V offset 0 V offset
3. Measure voltage V_out. ( )12(1
2 VV
R
RoutV , ako je
3
4
1
2
R
R
R
R )
Fig.27
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXVIII. Integrator
1. Connect electrical elements on protoboard as shown in Figure 28.
2. Set channel. CH1: Sine
1 kHz 1 Vpp Amp 0 V offset
3. Measure voltage V_out. ( dttinVCR
VoutV C )(21
12 )
Fig.28
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXIX. Integrator_2
1. Connect electrical elements on protoboard as shown in Figure 29.
2. Set channel. CH1: Sine
1 kHz 1 Vpp Amp 0 V offset
3. Measure voltage V_out. ( dttinVCR
outV )(21
1 )
Fig.29
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXX. Diferencijator
1. Connect electrical elements on protoboard as shown in Figure 30.
2. Set channel. CH1: Sine
1 kHz 0.5 Vpp Amp 0 V offset
3. Measure voltage V_out. (dt
tindVCRoutV
)(12
)
Fig.30
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POTREBNO
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXI. Instrumentacioni pojačavač
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Instrumentacioni pojačavač”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 31. Fig.31
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXII. Eksponencijalni pojačavač
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Eksponencijalni pojačavač”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 32. Fig.32
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXIII. Logaritamski pojačavač
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Logaritamski pojačavač”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 33. Fig.33
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXIV. Linearno preslikavanje opsega napona
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Linearno preslikavanje opsega napona”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 34. Fig.34
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXV. Instrumentacioni pojačavač
1. Connect electrical elements on protoboard as shown in Figure 35.
2. Set channels: CH1: DC 0.75 V
CH2: DC 1 V
3. Measure voltage V_out. ( 122
12
31
VV
R
R
R
RoutV
gain
)
Fig.35
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXVI. Eksponencijalni pojačavač
1. Connect electrical elements on protoboard as shown in Figure 36.
2. R = 0.1 k, 1 k and 10 k .
3. Set channel: CH1: DC 0.7 1 V
4. Measure voltage V_out. ( TU
inV
seIRoutV_
)
Fig.36
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXVII. Logaritamski pojačavač
1. Connect electrical elements on protoboard as shown in Figure 37.
2. R = 2.2 k, 3.3 k and 4.7 k .
3. Set channel: CH1: DC 1 5 V
4. Measure voltage V_out. (s
T IR
inVUoutV
ln )
Fig.37
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXVII. Linearno preslikavanje opsega napona
1. Connect electrical elements on protoboard as shown in Figure 38.
2. Set channel CH1: 2.1. Press ARB button
2.2. Press Edit button (menu) 2.3. Choose Operation 2.4. Choose Line 2.5. Set up From X1 = 1 Y1 = 1
To X2 = 1000 Y2 = 16382 2.6. Choose Execute 2.7. Press ARB button 2.8. Set up -Period 5s
-Amplitude 1V (Low level 0 V, High level 1 V)
3. Measure voltage S_out. ( VsensorR
R
RR
RoutS
2
3
45
5 1 )
Fig.38
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XXXIX. Superdioda
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Superdioda”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 39. Fig.39
4. Run the simulation (Simulate->Run).
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XL. Izvor referentnog napona
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Izvor referentnog napona”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 40. Fig.40
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLI. Triangular wave oscilattor
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Triangular wave oscillator”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 41. Fig.41
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLII. Detektor vrednosti (komparatori)
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Detektor vrednosti (komparatori)”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 42. Fig.42
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLIII. Superdioda
1. Connect electrical elements on protoboard as shown in Figure 43.
2. Set channel: CH1: Sine
1 kHz 200 mVpp Amp 0 V offset
3. Measure voltage Vout. Fig.43
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLIV. Izvor referentnog napona
1. Connect electrical elements on protoboard as shown in Figure 44.
2. Measure voltage Vout. Fig.44
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLV. Triangular wave oscilattor
1. Connect electrical elements on protoboard as shown in Figure 45.
2. Measure voltages V_sq and V_tri. Fig.45
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLVI. Detektor vrednosti (komparatori)
1. Connect electrical elements on protoboard as shown in Figure 46.
2. Measure voltages Vref, Vin and Vout. Fig.46
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLVII. Šmitovo kolo (komparatori)
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Šmitovo kolo (komparatori)”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 47. Fig.47
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLVIII. Schmitt trigger oscillator
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Schmitt_trigger_oscillator”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 48. Fig.48
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
XLIX. Schmitt trigger oscillator with zener diodes
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Schmitt_trigger_oscillator_zener”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 49. Fig.49
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
L. Šmitovo kolo (komparatori)
1. Connect electrical elements on protoboard as shown in Figure 50.
2. Measure voltages Vin and Vout. Fig.50
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LI. Schmitt trigger oscillator
1. Connect electrical elements on protoboard as shown in Figure 51.
2. Measure voltages Vc and V_out. Fig.51
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LII. Schmitt trigger oscillator with zener diodes
1. Connect electrical elements on protoboard as shown in Figure 52.
2. Measure voltage V_out. Fig.52
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LIII. Monostable Multivibrator
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Monostable Miltivibrator”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 53. Fig.53
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LIV. NE555 –Monostable Operation
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Monostable Operation”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 54. Fig.54
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LV. NE555 – Astable Operation
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Astable Operation”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 55. Fig.55
4. Run the simulation.
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LVI. Monostable Multivibrator
1. Connect electrical elements on protoboard as shown in Figure 569.
2. Measure voltage Vout. Fig.56
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LVII. NE555 –Monostable Operation
1. Connect electrical elements on protoboard as shown in Figure 57.
2. Measure voltage Vout. Fig.57
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LVIII. NE555 – Astable Operation
1. Connect electrical elements on protoboard as shown in Figure 58.
2. Measure voltage Vout. Fig.58
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ANALOGNA MIKROELEKTRONIKA Laboratorijske vežbe
LIX. NE555 – Missing-Pulse Detector
1. Create a new schematic (File->New Schematic...).
2. (File->Save as), name the schematic (for example “Missing-Pulse Detector”), and choose a safe place for it to be saved.
3. Now build the circuit shown in Fig. 59. Fig.59
4. Edit Netlist so that it is the same as the one listed below, name it (“PWL_missing.txt”) and choose a safe place for it to be saved. 0m 0 0.001m 3 0.08m 3 0.081m 0