yungman said:Usually it just does not displace the full amplitude, the rising and falling edge is slower than the real signal. If the signal is a lot higher in frequency, it might not even display any waveform, but show up as some DC offset.
berkeman said:It can also alias when its sampling frequency is too low for the input signal. That shows up as a nonsense waveform, or it can show up as a low-frequency waveform (which can be very confusing).
yungman said:Yes, I kept thinking about analog scope. For digital scope, you can have beat frequency that you can see low frequency patterns when the input frequency come close to half clock, clock frequency, 2 clock and so on. That's how I test the A to D front end when I was working for LeCroy long time ago. In fact, these are the most important test on how good the ADC is. You see missing codes using these beat frequency technique.
An oscilloscope is a scientific instrument used to measure and display electrical signals. It works by converting the electrical signal into a visual representation, typically a graph with a time axis and a voltage axis. The signal is measured and displayed as a waveform on the screen, allowing scientists to analyze and understand the behavior of the signal.
The range of an oscilloscope refers to the maximum and minimum values that can be displayed on the voltage axis. This range is determined by the sensitivity setting and the number of volts per division on the screen. For example, if the sensitivity is set to 1 volt per division and the screen has 10 divisions, the range would be 10 volts.
To adjust the range on an oscilloscope, you can use the vertical scale control or the volts/division knob. The vertical scale control allows you to change the sensitivity setting, while the volts/division knob allows you to adjust the number of volts per division on the screen. By changing these settings, you can adjust the range to suit your specific needs.
A wide range on an oscilloscope allows you to measure a variety of signals with different amplitudes. This is important because it allows you to accurately measure and analyze different types of signals, from small electronic signals to high voltage power signals. A wide range also gives you more flexibility and precision in your measurements.
Yes, it is possible to damage an oscilloscope by exceeding its range. If the voltage of the signal being measured is higher than the maximum range of the oscilloscope, it can cause damage to the instrument. It is important to always adjust the range appropriately before taking any measurements to prevent damage to the oscilloscope and ensure accurate readings.