To determine the wavelength from a graph, you can measure the distance between two consecutive peaks or troughs on the graph. This distance represents one full wavelength.
From a distance graph of a continuous wave as it propagates, you can determine the wavelength and the speed of the wave. By measuring the distance between corresponding points on the wave (e.g., peaks or troughs) you can calculate the wavelength. The speed of the wave can be calculated by dividing the wavelength by the time it takes for the wave to travel that distance.
To determine the phase constant from a graph, identify the horizontal shift of the graph compared to the original function. The phase constant is the amount the graph is shifted horizontally.
To determine the frequency of a given wavelength, you can use the formula: frequency speed of light / wavelength. The speed of light is a constant value, so by dividing it by the wavelength, you can calculate the frequency of the wave.
To determine velocity from an acceleration-time graph, you can find the area under the curve of the graph. This area represents the change in velocity over time. By calculating this area, you can determine the velocity at any given point on the graph.
To determine the frequency of a wavelength, you can use the formula: frequency speed of light / wavelength. The speed of light is a constant value of 3.00 x 108 meters per second. By dividing the speed of light by the wavelength, you can calculate the frequency of the wave.
To determine the wavelength using a spectrometer, you would pass light through the device and observe the resulting spectrum of wavelengths. The spectrometer will provide a readout or graph showing the intensity of light at different wavelengths, allowing you to identify the wavelength of interest based on the peak intensity. Additionally, calibrating the spectrometer with known wavelength sources can help accurately determine the wavelengths of unknown samples.
From a distance graph of a continuous wave as it propagates, you can determine the wavelength and the speed of the wave. By measuring the distance between corresponding points on the wave (e.g., peaks or troughs) you can calculate the wavelength. The speed of the wave can be calculated by dividing the wavelength by the time it takes for the wave to travel that distance.
To determine the initial value on a graph, look for the point where the graph intersects the y-axis. This point represents the initial value or starting point of the graph.
To determine the phase constant from a graph, identify the horizontal shift of the graph compared to the original function. The phase constant is the amount the graph is shifted horizontally.
To determine the frequency of a given wavelength, you can use the formula: frequency speed of light / wavelength. The speed of light is a constant value, so by dividing it by the wavelength, you can calculate the frequency of the wave.
The answer depends on what the graph is of: the distribution function or the cumulative distribution function.
To determine velocity from an acceleration-time graph, you can find the area under the curve of the graph. This area represents the change in velocity over time. By calculating this area, you can determine the velocity at any given point on the graph.
To determine the frequency of a wavelength, you can use the formula: frequency speed of light / wavelength. The speed of light is a constant value of 3.00 x 108 meters per second. By dividing the speed of light by the wavelength, you can calculate the frequency of the wave.
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To determine the natural frequency from a graph, identify the peak point on the graph which represents the highest amplitude or resonance. The frequency corresponding to this peak point is the natural frequency of the system.
To determine opportunity cost from a graph, you can look at the slope of the graph. The opportunity cost is represented by the ratio of the units of one good that must be given up to produce more units of another good. The steeper the slope of the graph, the higher the opportunity cost.
You would not use a graph to determine one person's height at a single point in time. You could use a line graph to track the height of a person over time. You could use a histogram to determine the heights of lots of people at one time.