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Related Concept Videos

Time and frequency -Domain Interpretation of Phase-lead Control01:24

Time and frequency -Domain Interpretation of Phase-lead Control

Phase-lead controllers are commonly used in various control systems to enhance response speed and stability. Adjusting the brightness on a television screen offers a practical example of phase-lead control. When contrast is enhanced, a phase-lead controller is employed. Mathematically, phase-lead control is identified when the first parameter is smaller than the second.
The design of phase-lead control involves the strategic placement of poles and zeros to balance steady-state error and system...
Gain01:15

Gain

Gain and phase shift are properties of linear circuits that describe the effect a circuit has on a sinusoidal input voltage or current. The circuit's behavior that contains reactive elements will depend on the frequency of the input sinusoid. As a result, it is observed that the gain and phase shift will all be frequency functions.
Gain:
Suppose Vin is the input and Vout is the output signal to a circuit.
Time and frequency -Domain Interpretation of Phase-lag Control01:21

Time and frequency -Domain Interpretation of Phase-lag Control

Phase-lag controllers are widely used in control systems to improve stability and reduce steady-state errors. A dimmer switch controlling the brightness of a light bulb serves as a practical example of phase-lag control, gradually adjusting the bulb's brightness. Mathematically, phase-lag control or low-pass filtering is represented when the factor 'a' is less than 1.
Phase-lag controllers do not place a pole at zero, but instead influence the steady-state error by amplifying any finite,...
Phase-lead and Phase-lag Controllers01:22

Phase-lead and Phase-lag Controllers

Understanding the working function of different types of controllers can be illustrated with practical analogies, such as adjusting a stereo's volume equalizer. Cranking up the bass involves a phase-lead controller, which functions as a high-pass filter, while increasing the treble uses a phase-lag controller, which acts as a low-pass filter. PD controllers, similar to high-pass filters, enhance the system's response to high-frequency components. PI controllers, akin to low-pass filters, manage...
Interference: Path Lengths01:10

Interference: Path Lengths

Consider two sources of sound, that may or may not be in phase, emitting waves at a single frequency, and consider the frequencies to be the same.
Two special sources may be considered when they are in phase. This can be easily achieved by feeding the two sources from the same source. An example would be synchronizing the two speakers by feeding them with the same source, such as the sound waves produced by a tuning fork. This setup ensures that the two sources have the same frequency and are...
Transformations of Functions II01:29

Transformations of Functions II

Transformations in mathematics alter the position or orientation of a function’s graph while preserving its fundamental shape. One important type of transformation is the horizontal shift, which involves modifying the input variable within a function’s equation. This operation affects where outputs occur along the horizontal axis but does not alter the function’s overall structure.A horizontal shift is achieved by replacing the input variable x with either x + c or x - c, where c is a constant.

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Shaping the Amplitude and Phase of Laser Beams by Using a Phase-only Spatial Light Modulator
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Published on: January 28, 2019

Window function influence on phase error in phase-shifting algorithms.

J Schmit, K Creath

    Applied Optics
    |December 4, 2010
    PubMed
    Summary
    This summary is machine-generated.

    We explored eight-point phase-shifting algorithms and found that window function shape significantly impacts phase error. Bell-shaped windows minimize errors, unlike simple rectangular or triangular ones, improving wavefront determination.

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    Area of Science:

    • Optical metrology
    • Wavefront sensing
    • Digital image processing

    Background:

    • Phase-shifting algorithms are essential for precise wavefront measurement.
    • Window functions in these algorithms critically affect phase error and measurement accuracy.
    • Existing algorithms often exhibit significant phase errors due to window function choice.

    Purpose of the Study:

    • To evaluate the impact of different window functions on eight-point phase-shifting algorithms.
    • To identify window function shapes that minimize phase error in wavefront determination.
    • To introduce an error-reducing multiple-averaging technique for algorithm development.

    Main Methods:

    • Developed five distinct eight-point phase-shifting algorithms.
    • Implemented rectangular, triangular, and bell-shaped window functions.
    • Utilized a novel error-reducing multiple-averaging technique.

    Main Results:

    • Algorithms with rectangular and triangular window functions exhibited substantial phase errors.
    • Algorithms employing bell-shaped window functions demonstrated significantly reduced sensitivity to phase error sources.
    • The choice of window function shape was shown to be a critical factor influencing overall phase error.

    Conclusions:

    • Bell-shaped window functions are superior for minimizing phase error in eight-point phase-shifting algorithms.
    • The developed algorithms offer improved accuracy in wavefront determination.
    • Window function design is a key consideration for robust optical metrology.