405I35B14M74560

Series:	405
Packaging:	Tape & Reel (TR)
Part Status:	Active
Type:	MHz Crystal
Frequency:	14.7456MHz
Frequency Stability:	±50ppm
Frequency Tolerance:	±30ppm
Load Capacitance:	13pF
ESR (Equivalent Series Resistance):	60 Ohms
Operating Mode:	Fundamental
Operating Temperature:	-40°C ~ 85°C
Ratings:	--
Mounting Type:	Surface Mount
Package / Case:	4-SMD, No Lead
Size / Dimension:	0.197" L x 0.126" W (5.00mm x 3.20mm)
Height - Seated (Max):	0.039" (1.00mm)

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。 Introduction to Crystals by 405I35B14M74560 Application Field and Working Principle Crystals are a class of materials that possess a regular and periodic arrangement of atoms. They are usually composed of a single type of atom, with a repeating pattern of crystal structure over large distances. These atoms may be of either organic or inorganic origin. Crystals are used for a variety of purposes in technology and engineering. The most common uses include semiconductor devices, optical fibers, and precision components for electronics. Crystals also find applications in many fields such as medicine, electronics, chemistry, metallurgy and metrology. The Application Field of Crystals 405I35B14M74560 Crystals have versatile applications in many industries. In the medical field, crystals are used in the construction of tissue imaging technology, imaging catheters, and drug delivery vehicles. Crystals are also widely used in the development of semiconductor devices such as transistors and photodetectors. The use of crystals in optical fiber telecommunications, consumer electronics, wireless communications and high-definition television is also common. In optical systems, crystals are widely used as optical convertors, frequency modulators, filters, and optical absorbers. In addition, crystal optical materials are used for many other purposes, such as signal processing, laser beam forming, imaging, optoelectronic signal conversion, and signal modulation. Due to the unique capabilities of crystals as optical convertors, they are also used as substitutes to optical fibers and ceramic optical elements. Crystals are also used in many military and aerospace applications, such as navigation systems, electronic countermeasures, and missile guidance systems. Due to their physical properties, crystals are ideal for the production of precision optics and cryogenic technologies. Crystal oscillators are also used in both military and civilian applications. The Working Principle of Crystals 405I35B14M74560 Crystals are used to control the flow of electrons in electronic devices. In this process, the energy required to move the electrons is supplied by radiowaves. The most commonly used crystals are those made from quartz or other synthetic materials. The principle of operation of a crystal is based on the principles of electromagnetism and the properties of a crystal structure. When an electric field is applied to the crystal structure, the electrons in the crystal structure move in a certain direction. This movement is referred to as polarization. When the electric field is removed, the electrons return to their original positions. As a result, when input and output signals are applied to a crystal, the electric current traveling through the crystal is regulated by the crystal structure. The output signal is then used as feedback to determine the position of the crystal\'s electron structure. The capacitance of a crystal is also an important factor in the operation of a crystal. A capacitor is an electronic component that stores electric energy. A crystal structure contains small capacitor elements which enable it to store a specific amount of energy. When an electric field is applied to the crystal, the energy stored in the crystal acts to oppose the electric field which, in turn, regulates the flow of electrons in the crystal. Crystals can also be used to create oscillating signals by altering their shape or by changing their properties. This is accomplished by stimulating the crystals with an alternating electric field. The movement of the electrons causes the crystal to vibrate, resulting in an oscillating signal. The frequency of the signal is determined by the physical properties of the crystal and by the application of the electric field. Conclusion) In conclusion, crystals 405I35B14M74560 have a wide range of uses in the fields of electronics, telecommunications, materials science, medicine, and aerospace engineering. Crystals are used for the generation, modulation, and conversion of optical signals, as well as for the transmission of signals in wireless communication systems and in sensor technologies. In addition, crystals are utilized in the manufacture of precision optics and cryogenic technologies. The working principle of crystals depends on the energy supplied by radiowaves and their ability to store electrical energy in the form of capacitor elements. It also relies on the properties of the crystal structure and the application of an alternating electric field to create oscillating signals.

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