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1 Alan Rux Electrical and Computer Engineering Department University of Massachusetts Lowell Campus Analog Discovery Design Kit Analog Discovery Design.

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Presentation on theme: "1 Alan Rux Electrical and Computer Engineering Department University of Massachusetts Lowell Campus Analog Discovery Design Kit Analog Discovery Design."— Presentation transcript:

1 1 Alan Rux Electrical and Computer Engineering Department University of Massachusetts Lowell Campus Analog Discovery Design Kit Analog Discovery Design Kit Mini Course Webinar lecture #2 of 4

2 2 Lecture # 2 Two Channel Oscilloscope & Arbitrary Waveform Generator Learning the ADK Leads (Analog Discovery Kit) Oscilloscope Operation F.F.T. Function

3 3 Leads are color coded

4 4 Leads we will be using today

5 5 You are now connected

6 6 To enable the oscilloscope click on the “Scope - in” icon

7 7 2 Channel Oscilloscope Window

8 8 2 Channel Oscilloscope Main Toolbar & Menu-Strip

9 9

10 10 2 Channel Oscilloscope Main Toolbar & Menu-Strip

11 11 2 Channel Oscilloscope Main Toolbar & Menu-Strip

12 12 2 Channel Oscilloscope Main Toolbar & Menu-Strip

13 13 2 Channel Oscilloscope Main Toolbar Persistence Add XY HistogramAudio FFTData MeasureCurrent AudioDigital EventsZoom OptionsHelp

14 14 Channel Toolbar Channel 1 & 2 Configuration (Vertical Gain, volts/cm )

15 15 Channel Toolbar Channel 1 & 2 Configuration (Vertical Gain, volts/cm ) Vertical Range 5V/div to 500uV/div In 1-2-5 steps

16 16 ChannelToolbar Channel 1 & 2 Configuration (Vertical Offset, volts/cm ) Offset Range +25V/div to -25V/div In 1-2-5 steps +/-100 mv., min. offset

17 17 Channel Toolbar Channel 1 & 2 Configuration (Horizontal Sweep, time/cm )

18 18 Channel Toolbar Channel 1 & 2 Configuration (Horizontal Sweep, time/cm ) Time Base 1hr./div to 10ns/div In 1-2-5 steps

19 19 Channel Toolbar Channel 1 & 2 Configuration (Trigger Position, time/cm ) Trigger Position +10hr./div to -10hr/div +/-5 usec., min. delay

20 20 Channel Toolbar Channel 1 & 2 Configuration (Trigger Configuration)

21 21 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Trigger Mode: Normal – triggered on specified condition Auto – triggered on trigger condition, self starts in 2 seconds None – the acquisition is started without a trigger

22 22 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Source: Channel 1 Channel 2 Digital AWG – 1 AWG – 2 Analyzer Patterns External – 1 External - 2

23 23 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Simple – is an edge trigger where the filter, hysteresis, and holdoff parameters are configured automatically. Level is set to 10% of the selected trigger channel range

24 24 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Edge + slope-condition control

25 25 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Pulse, will trigger if pulse has a smaller/larger length than the one set by the user. Set for Less then 200 usec.

26 26 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Pulse, will trigger if pulse has a smaller/larger length than the one set by the user. Set for more then 200 usec.

27 27 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Transition - the transition time of a signal as compared with a specified length

28 28 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Type of Trigger: Transition - the transition time of a signal as compared with a specified length

29 29 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Trigger Hysteresis – low and high leveles are determined to avoid bouncing caused by signal noise and also to specify the transition trigger conditions, 20 volts to 1mv and zero volts in 1 -2 -5 steps

30 30 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Trigger Hysteresis

31 31 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION) Trigger Holdoff – a adjustable time period during which the oscilloscope will not trigger. this is useful when triggering on complex waveform shapes, so the oscilloscope triggers only on the first eligible trigger point. Time range from 1 hour to 100nsec., in 1 – 2 – 5 steps and zero sec.

32 32 CHANNEL TOOLBAR CHANNEL 1 & 2 (TRIGGER CONFIGURATION)

33 33 CHANNEL TOOLBAR CHANNEL 1 & 2 (OPTIONS CONFIGURATION) Options: General, Display, Colors, Configuration

34 34 CHANNEL TOOLBAR CHANNEL 1 & 2 (COLOR CONFIGURATION)

35 35 CHANNEL TOOLBAR CHANNEL 1 & 2 (COLOR CONFIGURATION)

36 36 Main Toolbar F. F. T. function FFT View – plots amplitude against frequency, it shows the signals in the frequency domain as opposed to the time domain

37 37 2 Channel Oscilloscope Main Toolbar – FFT function

38 38 Arbitrary Waveform Generator the ADK Leads (Analog Discovery Kit) Function Generator operation Oscilloscope use

39 39 Leads are color coded

40 40 Leads we will be using today

41 41 Leads we will be using today Waveform Gen-1 (yellow) to Scope ch-1 (orange) Waveform Gen-1 common gnd. (black) to Scope ch-1 neg. (orange/white)

42 42 Analog Discovery BNC Adapter Board Allows the use of standard BNC- terminated test leads & probes on your Analog Discovery Selectable AC and DC coupling to oscilloscope probes Selectable 50-ohm or 0-ohm output impedance on Arbitrary Waveform Generator (AWG) channels

43 43 You are now connected

44 44 To enable the Waveform Gen. click on the “WaveGen - out” icon

45 45 Waveform Generator Window 1 Channel, AWG-1

46 46 also enable the oscilloscope click on the “Scope - in” icon

47 47 2 Channel Oscilloscope Window

48 48 Waveform Generator Window AWG-1 & AWG-2

49 49 Waveform Gen./Scope Window 1 Channel Oscilloscope & AWG-1 AWG scope

50 50 AWG main window

51 51 Waveform Channel Control Enable / Disable button Run / Stop button Idle output/Repeat Trigger Initial Value Offset High Z 0 V.

52 52 Waveform Mode Control Standard Mode DC Level Sine Square Triangle Ramp-up Ramp-down Noise Triangle-Square Sine-Power

53 53 Mode Control Frequency Mode slider Frequency Range 10 MHz 100 uHz 1 – 2 – 5 steps MHz, KHz, Hz, mHz, uHz

54 54 Mode Control Amplitude Mode slider Amplitude Range 5 volts peak max 0 volts 1 – 2 – 5 steps Volts,,mVolts 50 mVolt limit

55 55 Mode Control Offset Mode slider Offset Range volts DC reference point +5 to -5 volts DC 1 – 2 – 5 steps 30 mVolts min step

56 56 Mode Control Symmetry Mode slider Symmetry Range ( square/pulse wave ) 100 to 0 % duty cycle 1 % steps

57 57 Mode Control Phase Mode slider Phase Range 360 to 0 degrees 1 degrees steps

58 58 Signal Preview Plot

59 59

60 60

61 61

62 62 Sweep Configuration Mode

63 63 Sweep Configuration Mode

64 64 Sweep Configuration Mode

65 65 Sweep Configuration Mode standard carrier

66 66 Sweep Configuration Mode standard carrier Frequency 10 MHz to 100uHz 1 – 2 – 5 steps

67 67 Sweep Configuration Mode standard carrier Amplitude Range +/- 5 volts 1 – 2 – 5 steps for volts 1000mv to 100mv/100mv steps 100mv to 0v / 10 mv steps Volts,,mVolts 10 mVolt limit

68 68 Sweep Configuration Mode standard carrier Offset +/_ 5volts 1 – 2 – 5 steps for volts 1000mv to 100mv/100mv steps 100mv to 50mv / 10 mv steps Volts,,mVolts 50 mVolt min.

69 69 Sweep Configuration Mode

70 70 Sweep Configuration Mode Sweep mode and Damp mode Sweep – FM modulation – AM modulation

71 71 Sweep Configuration Mode Burst Signals

72 72 Sweep Configuration Mode Burst Signals

73 73 Carrier Modulation carrier signal 50 KHz, modulation signal 1 KHz, FM modulation

74 74 Carrier Modulation carrier signal 50 KHz, modulation signal 1 KHz, AM modulation

75 75 Carrier Modulation carrier signal 50 KHz, modulation signal 1 KHz, FM & AM modulation

76 76 Sweep Configuration Arbitrary Waveform Editor

77 77 Questions?

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