0
Troughs on a graph from an oscilloscope represent the points of minimum amplitude in a waveform, indicating the lowest voltage levels during a signal cycle. In a typical sinusoidal wave, these troughs correspond to the negative peaks, where the signal is at its lowest. Analyzing these troughs can provide insights into the characteristics of the signal, such as frequency, amplitude, and phase.
What else can I help you with?
Where is break even on quadratic graph?
It depends on what variable is represented by the graph.
what is the domain of the function represented by the graph?
there is no graph... but most chance it's all real numbers
A genetic cross can be represented in a graph in the form of what?
A Punnet Square
What does a nonlinear graph look like?
any graph that is not represented by a line,ie: parabola, hyperbola, circle, ellipse,etc
What type of a graph shows the relationship between two variables?
A line graph.
How is the amplitude of a sound represented?
The amplitude of a sound is typically represented by the height or intensity of the sound wave. In a waveform graph, the amplitude is shown by the distance between the peaks and troughs of the wave. The greater the amplitude, the louder the sound.
How can one determine the wavelength from a graph?
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.
What does the line on a graph from an oscilloscope represent?
The waveform of the electrical signal in terms of amplitude on y and period in x.
How is the loudness of a sound on an oscilloscope?
The loudness of a sound is represented by the amplitude of the wave displayed on an oscilloscope. Higher amplitudes indicate louder sounds, while lower amplitudes indicate quieter sounds. The vertical axis of the oscilloscope shows the amplitude of the sound wave.
Where is break even on quadratic graph?
It depends on what variable is represented by the graph.
What is the maximum voltage Vmax of the signal How did you determine it from the oscilloscope graph?
The maximum voltage ( V_{max} ) of the signal can be determined by analyzing the oscilloscope graph, specifically by identifying the highest peak value of the waveform. This peak corresponds to the highest vertical point on the graph, which represents the maximum voltage amplitude of the signal. By observing the vertical scale (volts per division) and counting the number of divisions from the baseline to the peak, you can calculate ( V_{max} ) and confirm it using the oscilloscope's measurement tools if available.
What happens to waveform on oscilloscope when we increase the voltage level from function generator?
When the voltage level from the function generator is increased, the waveform displayed on the oscilloscope will rise in amplitude, appearing taller on the vertical axis. The shape of the waveform remains the same, whether it's a sine, square, or triangle wave, but the peaks and troughs will be more pronounced. Additionally, if the vertical scale on the oscilloscope is not adjusted, the waveform may clip if the voltage exceeds the oscilloscope's maximum input range.
What kind of graph is pictographs?
A graph that has its data represented in little symbolic pictures.
How is speed and acceleration represented on a graph?
Speed is represented by the slope of a distance-time graph, where steeper slopes indicate faster speed. Acceleration is represented by the slope of a speed-time graph, where a steeper slope indicates a greater acceleration.
What is the visual representation of sound?
Sound waves are typically represented visually as waveforms, which depict the amplitude (volume) of the sound over time. These waveforms can be displayed as a series of peaks and troughs on a graph or as a waveform in audio editing software. Additionally, sound can be represented in a spectrogram, which shows how the sound's frequency content changes over time.
Which of the inequalities is represented by the graph?
.08>0.4
Which equation is represented by the graph?
The equation of invisibility!
