Search
Log in
Login:
Password:
Register
Forgot your password?

ADS-5102 Digital Storage Oscilloscope

Digital storage oscilloscope. Dual channels. Analog Bandwidth: 100MHz. Real-time Sample rate: Half Channel-2GSa/s; Each Channel-1GSa/s. Equivalent Sample rate: 50GSa/s. Memory Depth: 24K single channel. Trigger Modes: Edge, Pulse, Video, Slope and Alternative trigger modes. Unique Digital Filter function and Waveform recorder function. Pass/Fail function. 32 parameters Auto measure function. Display: 7" color TFT-LCD, 480x234 pixels. Weight: 10lb/4.5kg. Size: 14×6×4,6in/358×156×118mm (L×W×H).

Manuals: 
User's Manual (1.99 Mb)

Features

  • Memory depth is 24Kpts
  • Use Colored TFT LCD, the waveform display is clearer and stable
  • Screen saver function: 1 minute to 5 hours
  • The real time sampling rate is 2GSa/s
  • Trigger Modes: Edge, Pulse, Video, Slope and Alternative trigger modes
  • Unique Digital Filter function and Waveform recorder function
  • Pass/Fail function
  • Thirty two parameters Auto measure function
  • Cursor measure covers Manual mode, Track mode and Auto mode
  • Channel waveform and it’s FFT waveform display on split screen
  • Pop-up Menu display pattern is more convenient for users using it
  • Multiple Language User Interface
  • Support Multilingual online help system

General Specification List:

Specification Table:

Input:

Input Coupling AC, DC, GND
Input Impedance 1MΩ±2% || 17pF±3pF
Maximum input voltage 400V (DC+AC PK-PK, 1MΩ input impedance), CAT I, CAT II
Probe attenuator 1X, 10X
Probe attenuator Factors Set 1X, 10X, 100X, 1000X

Horizontal System:

Real Time Sampling Rate 4Kpts memory depth Series:
Single Channel: 500MSa/s, Double Channel: 250MSa/s (When time base faster than 250ns/div)
32K/40K/2Mpts memory depth Series:
Single Channel: 1GSa/s, Double Channel: 500MSa/s (When time base faster than 50ns/div)
5Kpts/CH memory depth Series: 1GSa/CH
18K/24Kpts memory depth Series: 2GSa/CH
Equivalent Sampling Rate 50GSa/s (40MHz bandwidth: 25GSa/S; 25MHz bandwidth: 10GSa/s)
Measure Display Modes MAIN, WINDOW, WINDOW ZOOM, SCAN, X-Y
Time base Accuracy Horizontal Scan Range ±100ppm measured over 1ms interval
1/2.5/5/10/25ns/div - 50s/div (According to the Bandwidth)
SCAN: 100ms/div - 50s/div (1-2.5-5 sequence)

Vertical System:

Vertical Sensitivity 4K/15K/118K/124Kpts memory depth Series:
2mV/div - 5V/div (1-2-5 order)
32K/140K/2Mpts memory depth Series:
2mV/div - 10V/div (1-2-5 order)
Channel Voltage Offset Range 4K/5K/18K/24Kpts memory depth Series: 2mV-100mV: ±2V
102mV-5V: ±40V
32K/40K/2Mpts memory depth Series: 2mV-200mV: ±1.6V
206mV-10V: ±40V
Vertical Resolution 8 bit
Channels 2
Analog Bandwidth 100MHz
Single-shot Bandwidth 100MHz
Lower frequency limit (AC-3dB) ≤10Hz (at input BNC)
DC Gain Accuracy ≤±3.0%: 5mV/div to 10mV/div in Fixed Gain Ranges
≤±4.0%: typical for 2mV/div and Variable Gain Ranges
DC Measurement Accuracy: All Gain settings ≤100mV/div ± [3%X(|reading|+|offset|)+1% of |offset|+0.2div+2mV]
Rise time <3.5ns
Vertical input coupling AC, DC, GND
Math operation (+),( -), (*), (/), FFT
FFT Window mode: Hanning, Hamming, Blackman, Rectangular
Sampling points: 1024
Digital storage oscilloscope 20MHz±40% Typical
(Note: 25MHz bandwidth oscilloscope don't have this function, BW limited below 20MHz±40% when using probe X1)

Measure System:

Auto Measure (32 Types) Vpp, Vmax, Vmin, Vamp, Vtop, Vbase, Vavg, Mean, Crms, Vrms, ROVShoot, FOVShoot, RPREShoot, FPREShoot, Rise time, Fall time, Freq, Period, +Wid, -Wid, +Dut, -Dut, Bwid, Phase, FRR, FRF, FFR, FFF, LRR, LRF, LFR, LFF
Cursor Measure Manual mode, Track mode and Auto mode

Trigger System:

Trigger Types Edge, Pulse, Video, Slope , Alternative
Trigger Source CH1, CH2, EXT, EXT/5, AC Line
Trigger Modes Auto, Normal, Single
Trigger Coupling AC, DC, LF rej, HF rej
Trigger Level Range CH1, CH2, CH3, CH4: 6 divisions from center of screen
EXT: 1.2V
EXT/5: 6V
Trigger Displacement Pre-trigger: (Memory depth / (2*sampling))
Delay Trigger: 260div
Holdoff range 100ns-1.5s
Edge Trigger Edge type: Rising, Falling, Rising and Falling
Pulse Width Trigger Trigger Modes: ( > , <, = ) Positive Pulse Width, ( >, <, = ) Negative Pulse Width
Pulse Width Range: 20ns-10s
Video Trigger Support signal Formats: PAL/SECAM, NTSC
Trigger condition: odd field, even field, all lines, line Num
Slope Trigger ( > , <, =) Positive slope, ( > , <, =) Negative slope
time: 20ns-10s
Alternative Trigger CH1, CH2, CH3, CH4 trigger type: Edge, Pulse, Video, Slope

Hard Ware Frequency Counter:

Reading resolution 6 bytes
Range DC Couple, 10Hz to Max Bandwidth
Signal Types Satisfying all Trigger signals (Except Pulse width trigger and Video Trigger)

X-Y Mode:

X-pole Input Channel 1 (CH1) / Channel 2 (Ch2) or
Y-pole Input Channel 1 (CH3) / Channel 2 (Ch4)
Phase Error ±3 degrees
Sample Frequency XY mode has a breakthrough that trade oscilloscopes restrict sampling rate at 1MSa/s and 4Kpts memory depth Series supports 5kSa/s~200MSa/s
32K/40K/2Mpts memory depth Series: supports 25kSa/s~100MSa/s, 2GSa/s real-time series supports: 10kSa/s~1GSa/s

Control Panel Function:

Auto Set Auto adjusting the vertical, Horizontal system and Trigger Position
Save/Recall Support 2 / 4 Group referenced Waveforms, 20 Group setups, 20 Group captured Waveforms internal Storage/Recall function and USB flash driver storage function.

Acquisition System:

Sample Types Real time, Equivalent time
Peak Detect Captures glitches down to 1Ons wide regardless of sample rate
Sample Mode Sample, Peak Measure, Average
Averages 4, 16, 32, 64, 128, 256

Generic Specification:

Display System:

Display Mode Color TFT 7in. (178mm) diagonal Liquid Crystal Display
Display Mode 480 horizontal by 234 vertical pixels
Display Color 64K color
Display Contrast (Typical state) 150:1
Backlight Intensity (Typical state) 300nit
Wave display range 8x18div
Wave display mode Point, Vector
Persist Off, 1sec, 2sec, 5sec, Infinite
Menu Display 2sec, 5sec, 10sec, 20sec, Infinite
Screen-Saver Off, 1min, 2min, 5min, 10min, 15min, 30min, 1hr, 2hr, 5hr
Skin Classical, Modern, Tradition, Succinct
Waveform interpolation Sin(x)/x, Linear
Color model Normal, Invert
Languages Simplified Chinese, Traditional Chinese, English, Arabic, French, German, Russian, Spanish, Portuguese, Japanese, Korean, Italian

Environments:

Temperature Operating: 50°F to 104°F / 10°C to 40°C
Not operating: -4°F to 140°F / -20°C to 60°C
Cooling The fan forces it cold.
Humidity Operating: 85%RH 104°F/40°C, 24 hours
Not operating: 85%RH 149°F/65°C, 24 hours
Height Operating: at 0 to 9843 feet/3000 meters; Not operating: after 50085 feet/15,266 meters

Power Supply:

Input Voltage 100-240VAC, CAT II, Auto selection
Frequency Scope 45Hz to 440Hz
Power 50VA Max

Mechanical:

Dimension Length 12"/305mm
Width 5 ¼"/133mm
Height 6 1/8"/154mm
Weight 5.1lb/2.3kg

Accessories

  • Passive Probes x 2

  • Power Cord

  • USB Cable

  • CD-ROM (including User Guide and Application Software)

  • User Manual

Analyze the signal detail

You have a noisy signal displayed on the oscilloscope and you need to know more about it. You suspect that the signal contains much more detail than you can now see in the display.

Looking at a Noisy Signal

The signal appears noisy and you suspect that noise is causing problems in your circuit. To analyze the noise better, follow these steps:

  • Press the ACQUIRE button to see the acquire menu.
  • Press the Acquisition option button or turn the Universal knob to select Peak Detect.
  • If necessary, press the DISPLAY button to see Display menu. Turn the Universal knob to adjust waveform intensity and grid brightness to see the noise more clearly.
  • Peak detect emphasizes noise spikes and glitches in your signal, specially when the time base is set to a slow setting.

Separating the Signal from Noise

To reduce random noise in the oscilloscope display, follow these steps:

  • Press the ACQUIRE button to display the acquire menu.
  • Press the Acquisition option button or turn the Universal knob to select Average.
  • Press the Averages option button to see the effects of varying the number of running averages on the waveform display.

Averaging reduces random noise and makes it easier to see the details of a signal.

Analyzing a Differential Communication Signal

You are having intermittent problems with a serial data communication link, and you suspect poor signal quality. Set up the oscilloscope to show you a snapshot of the serial data stream so you can verify the signal levels and transition times.

Because this is a differential signal, you use the math function of the oscilloscope to view a better representation of the waveform.

To activate the differential signals connected to channel 1 and channel 2, follow these steps:

  • Press the CH1 button and set the Probe option attenuation to 10X.
  • Press the CH2 button and set the Probe option attenuation to 10X.
  • Set the switches to 10X on the probes.
  • Press the AUTO button.
  • Press the MATH button to see the Math Menu.
  • Press the Operation option button and select - .
  • Press the CH1-CH2 option button to display a new waveform that is the difference between the displayed waveforms.
  • You can adjust the vertical scale and position of the Math waveform.
    To do so, follow these steps:
    A. Remove the channel 1 and channel 2 waveforms from the display.
    B. Turn the CH1 and CH2 VOLTS/DIV and VERTICAL POSITION knobs to adjust the vertical scale and position.

Note: First be sure to compensate both probes. Differences in probe compensation appear as errors in the differential signal.

Application of X-Y function

Viewing Impedance Changes in a Network

Connect the oscilloscope to monitor the input and output of the circuit. To view the input and output of the circuit in an X-Y display, follow these steps:

  • Press the CH1 MENU button and set the Probe option attenuation to 10X.
  • Press the CH2 MENU button and set the Probe option attenuation to 10X.
  • Set the switch of the probe to 10X.
  • Connect the channel 1 probe to the input of the network, and connect the channel 2 probe to the output.
  • Press the AUTO button.
  • Turn the Volts/div knobs to display approximately the same amplitude signals on each channel.
  • Press the DISPLAY button.
  • Press the Format option button and select XY.

The oscilloscope displays a Lissajous pattern representing the input and output characteristics of the circuit.

  • Turn the VOLTS/DIV and VERTICAL POSITION knobs to optimize the display.
  • Press the Persist option button and select Infinite.
  • Press the Intensity or Brightness option buttons and turn the Universal” knob to adjust the contrast of the screen.
  • Apply the Ellipse method to observe the phase difference between the two channels

Application of X-Y function

Sin=A/B or C/D where =phase shift (in degrees) between the two signals from the formula above, you could get:=arcsine(A/B) or arcsine(C/D). If the main axis of the ellipse is at I and IV quadrant, must be in the range of (0~π/2) or (3π/2~2π). If the main axis is at II and III quadrant, must be in the range of (π/2~π) or (π~3π/2).

Catch the single signal

To capture a single event, you need to gather some pre-test knowledge of the signal in order to correctly set up the trigger level and slope. If you are not sure the instance of the signal, you can observe it through auto or normal trigger mode to ensure the trigger level and slope.

The following steps show you how to use the oscilloscope to capture a single event.

1. Set the Probe option attenuation to 10X and set the switch to 10X on the probe.
2. Trigger set up:

  • Press “TRIG MENU” button to show the “Trigger Menu”
  • Under this menu, set the trigger type to “edge”, Edge type is “Rising”, source is “CH1”, trigger mode is “Single”, coupling is “DC”
  • Adjust the horizontal time base and vertical scale to the satisfied range
  • Turn the “LEVEL” knob to adjust the trigger level
  • Press the “RUN/STOP” button to start capturing

When the trigger conditions are satisfied, data appears on the display representing; the data points that the oscilloscope obtained with one acquisition and press the RUN/STOP button again rearms the trigger circuit and erases the display.

Taking Cursor Measurements

You can use the cursors to take time and voltage measurements of a waveform quickly.

Measuring Ring Frequency

To measure the ring frequency at the rising edge of a signal, follow these steps:

  • Press the CURSORS button to see the Cursor Menu.
  • Press the Mode button to select Manual.
  • Press the Type option button and select Time.
  • Press the Source option button and select CH1.
  • Press the Cur A button and turn the universal knob to place the cursor A on one peak of the ring.
  • Press the Cur B button and turn the universal knob to place the cursor B on the nearest peak of the ring.

You can see the delta time and frequency (the measured ring frequency) on the top left of the screen.

Measuring Ring Frequency

Measuring Ring Amplitude

To measure the amplitude, follow these steps:

  • Press the CURSORS button to see the Cursor Menu.
  • Press the Mode button to select Manual.
  • Press the Type option button and select Voltage.
  • Press the Source option button and select CH1.
  • Press the Cur A option button and turn the universal knob to place the cursor A on the highest peak of the ring.
  • Press the Cur B option button and turn the universal knob to place the cursor B on the lowest peak of the ring.

You can see the following measurements on the top of the left screen:

  • The delta voltage (peak-to-peak voltage of the ringing)
  • The voltage at Cursor A.
  • The voltage at Cursor B.

Measuring Ring Amplitude

Taking Simple Measurements

Observe a unknown signal in a circuit, display the signal quickly and measure the frequency and peak-to-peak amplitude.

1. Using Auto set

To quickly display a signal, follow these steps:

  • Press the CH1 button, set the Probe option attenuation to 10X and set the switch to 10X on the probe.
  • Connect the channel 1 probe to the signal.
  • Press the AUTO button.

The oscilloscope sets vertical, horizontal, and trigger controls automatically. If you want to optimize the display of the waveform, you can adjust these controls manually till you are satisfied with the waveforms.
Note: The oscilloscope displays relevant automatic measurements in the waveform area of the screen based on the signal type detected.

2. Taking Automatic Measurements

The oscilloscope can take automatic measurements of most displayed signals. To measure signal frequency and peak-to-peak amplitude, follow these steps:

(1) Measure signal frequency

  • Input the signal to channel 1.
  • Press the AUTO button.
  • Press the MEASURE button to see auto Measure Menu.
  • Press the top option button.
  • Press the Time option button to enter the Time Measure menu.
  • Press the Source option button to select input signal channel.
  • Press the Type option button to select Freq.
    The corresponding icon and measure value will display on the third option area.

(2) Measure signal peak-to-peak amplitude

  • Press the MEASURE button to display auto measure menu.
  • Press the top second option button.
  • Press the Voltage option button to enter the Voltage measure menu.
  • Press the Source option button to select input signal channel.
  • Press the Type option button to select Vpp.
    The corresponding icon and measure value will display on the third option area.

Triggering on a Video Signal

Observe the video circuit in a piece of medical equipment and Use the video trigger to obtain a stable display.

Triggering on Video Field

To trigger on the video fields, follow these steps:

  • Press the TRIGGER MENU button to see trigger menu
  • Press the top option button and select Video.
  • Press the source option button and select Ch1.
  • Press the Sync option button and select Odd Field or Even Field.
  • Press the Standard option button and select NTSC.
  • Turn the horizontal S/Div knob to see a complete field across the screen.
  • Turn the vertical Volts/Div knob to ensure that the entire video signal is visible on the screen.

Triggering on Video Lines

To trigger on the video lines, follow these steps:

  • Press the TRIGGER MENU button to see the trigger menu
  • Press the top option button and select Video.
  • Press the Sync option button and select Line Num and turn the universal knob to set a specific line number.
  • Press the Standard option button and select NTSC.
  • Turn the S/Div knob to see a complete video line across the screen.
  • Turn the Volts/Div knob to ensure that the entire video signal is visible on the screen.

Frequently Asked Questions

  • After pressing the RUN/STOP button, the oscilloscope does not display any waveform
  • After the Acquisition is set to "Averages" or Display Persistence is set ON, the waveform refreshes slowly
  • The measured voltage amplitude value is 10 times greater or smaller than the actual value
  • After the oscilloscope is powered on the display remains dark, what should I do?
  • The signal is displayed as ladder like waveform
  • There is wave form displayed, but it is not stable
  • When changing the horizontal sweep on the digital oscilloscope at different horizontal points observed inexplicable change in the form of the same signal, why is this happening?

  • After pressing the RUN/STOP button, the oscilloscope does not display any waveform
    Check whether the Trigger Mode is set to "Normal" or "Single" and see whether the trigger level is out of the signal range. If yes, set the trigger level in proper range by turning the LEVEL knob or pressing the 50% button. Or set the Trigger Mode as "AUTO". Moreover, push AUTO button to display the waveform on screen.
    Up

    After the Acquisition is set to "Averages" or Display Persistence is set ON, the waveform refreshes slowly
    It is normal in these settings.
    Up

    The measured voltage amplitude value is 10 times greater or smaller than the actual value
    Check whether the channel attenuation coefficient and the attenuation coefficient of the probe used is match.
    Up

    After the oscilloscope is powered on the display remains dark, what should I do?

    Please implement the following fault treatment procedure.

    • Check whether the power cable is connected properly.
    • Ensure the power switch is turned on.
    • Restart the instrument after completing the checks above.
    • If the oscilloscope still can not work normally, please call for service.

    Up

    The signal is displayed as ladder like waveform
    1. The time base setting maybe is too slow. Turn the horizontal SCALE knob to increase horizontal resolution.
    2. Maybe the display Type is set to "Vectors". Set it to "Dots" mode.

    Up

    There is wave form displayed, but it is not stable
    • Check whether the Source item in the TRIG MODE menu is in conformity with the signal channel used in the practical application.
    • Check on the trigger Type item: The common signal chooses the Edge trigger mode for Type and the video signal the Video. Only if a proper trigger mode is applied, the wave form can be displayed steadily.
    • Try to change the trigger coupling into the high frequency suppress and the low frequency suppress to smooth the high frequency or low frequency noise triggered by the interference.

    Up

    When changing the horizontal sweep on the digital oscilloscope at different horizontal points observed inexplicable change in the form of the same signal, why is this happening?

    In fact, this is not a problem.

    Just keep in mind that you're using a digital oscilloscope, which digitizes the signal with different sampling rates depending on the selected horizontal sweep, and then connects the digitized points with strait line while restoring the real shape of the signal.

    Your first screen shows that you are measuring voltage 50 Hz with the 10 ms / div sweep and a sampling frequency of 20 kHz Ks/s

    One signal period (20 ms), digitized in this mode, 20E-03 (sec) * 20E03 (1/sec) = 400 points. This is enough to properly restore and interpolate a sine wave of 50 Hz (i.e. in a period of 20 ms).

    Normal display, with a sweep 10 ms / div:

    Distortion of the same signal at 10 s / div sweep

    Your second screen is set to sweep 10 sec / div, and sample rate on a sweep turned to 20 samples per second (20 Sa / s). I.e. one signal period 20 ms had: 20E-03 (sec) * 20 (1/sec) = 0.4 points. That means that to restore (to interpolate the points) a sine wave with less than one point in time is impossible, so you get this mess (known as "aliasing" or a false frequency) formed by the beats of the measured frequency and sampling frequency.

    In order to correctly install a data collection in a digital oscilloscope one should follow a simple rule - the sampling rate must be at least 5-10 times higher than the frequency signal, in that case you will not have the issues that we just discussed.

    This applies to all digital oscilloscopes and in no way connected to any particular make or model of oscilloscope or its probes.


    Up


    Back to the section