Allicdata Part #: | 250-15060-ND |
Manufacturer Part#: |
250-15060 |
Price: | $ 0.00 |
Product Category: | Crystals, Oscillators, Resonators |
Manufacturer: | Parallax Inc. |
Short Description: | CER RES 50.0000MHZ SMD |
More Detail: | 50MHz Ceramic Resonator |
DataSheet: | 250-15060 Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Series: | ZTT |
Packaging: | -- |
Part Status: | Obsolete |
Type: | Ceramic |
Frequency: | 50MHz |
Frequency Stability: | -- |
Frequency Tolerance: | -- |
Features: | -- |
Operating Temperature: | -- |
Mounting Type: | -- |
Package / Case: | -- |
Size / Dimension: | -- |
Height: | -- |
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Resonators are devices that absorb and emit sound energy. They are used in a wide range of applications, such as medical imaging, automotive systems, aeronautical systems and security systems. In this article, we will discuss the application field and working principle of resonators.
Application Field of Resonators
Resonators are used for sound wave absorption and emission in a variety of applications. In medical imaging, they are used to detect and analyze sound waves emitted by body tissue. This information is used to detect abnormalities such as cancers or other disease conditions. In automotive systems, they are used to monitor engine vibrations, detect threats to the vehicle, and create audio feedback for the driver. In aeronautical systems, they are used to detect and identify objects in the atmosphere. For example, they can be used to detect aircraft flying in unsafe altitudes. Finally, in security systems, they are used to detect acoustic disturbances, such as screams or breaking glass.
Working Principle of Resonators
Resonators create a vibration in response to an incoming sound wave. This vibration causes the resonator to absorb the energy of the sound wave. The absorbed energy is then released in the form of a reflected sound wave. This process can be used to create a three-dimensional image of the area in which the resonator is located.
The amount of energy absorbed and emitted by the resonator is determined by its resonant frequency. This is the frequency at which the resonator vibrates. The resonant frequency of a resonator is determined by its size and material composition.
Resonators are also used to create complex audio effects. When two resonators are placed in close proximity, they create a feedback loop. The two resonators interact with each other, creating a distinct soundscape. This phenomenon is exploited to create various audio effects in modern music production.
Resonators are also used for communication applications. When a sound wave is sent through a resonator, the receiver can detect the unique pattern created by the resonator. This pattern can be used to encrypt and transmit data securely.
Conclusion
Resonators are versatile devices that are used in a variety of applications. They are used to absorb and emit sound waves, create audio effects, and transmit data securely. Their application field and working principle have been discussed in this article.
The specific data is subject to PDF, and the above content is for reference
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