Depends on the model.
For a scientific unit I'd expect 100 parts-per-million or better - try an online search to find typical models and check the specs.
The uncertainty of an oscilloscope can affect the accuracy of electronic measurements by introducing errors or variations in the displayed waveform, leading to inaccuracies in voltage, frequency, and timing measurements.
The electronic balance was invented by German physicist Fritz Knop in 1960. He designed it as a more accurate and automated alternative to traditional mechanical balances.
A digital balance or electronic scale would be the most accurate and precise instrument to determine the mass of a toy car. These devices can measure mass to a high degree of accuracy and are commonly used in scientific settings for precise measurements.
A triple beam balance or electronic balance will be used to measure the mass of an irregular solid. The object is placed on the balance, and the reading of the balance will indicate the mass of the irregular solid.
The balance can measure the mass of a substance ranging from milligrams to kilograms. It is important to consider the sensitivity and accuracy of the balance when selecting the appropriate range for measurement.
No a trial balance does not determine the accuracy of numbers. It only tests the accuracy, if done right.
The accuracy to which you can take into account the mass of the spring, and the accuracy and consistency of spring tension data inherently limit the accuracy of an inertial balance.
It has an accuracy to 0.01s.
it a electronic balance to measure weight
it a electronic balance to measure weight
Electronic balances need no such known masses once they have been properly calibrated. Analytical balances are very accurate and until the advent of semiconductors were the only scales available.
A digital balance can be used to measure the weight of different foods and spices. It can also be used to weigh letters.
Electronic balance is a balance that generates lots of currents which displaces the pan. It is used in labs to weight substances electronically.
There is no tolerance for errors at all. So the accuracy is expected to be absolute.
An electronic balance is typically more precise than a beam balance because electronic balances can measure weight to smaller decimal points, providing more accurate results. Beam balances rely on manual adjustments and reading of weights, which can introduce more room for human error compared to the automated measurements of an electronic balance.
You can use a triple beam balance or an electronic balance.
The uncertainty of an oscilloscope can affect the accuracy of electronic measurements by introducing errors or variations in the displayed waveform, leading to inaccuracies in voltage, frequency, and timing measurements.