Allicdata Part #: | 768-143-R330-ND |
Manufacturer Part#: |
768143331G |
Price: | $ 0.00 |
Product Category: | Resistors |
Manufacturer: | CTS Resistor Products |
Short Description: | RES ARRAY 7 RES 330 OHM 14SOIC |
More Detail: | 330 Ohm ±2% 200mW Power Per Element Isolated 7 Res... |
DataSheet: | 768143331G Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Number of Pins: | 14 |
Height - Seated (Max): | 0.071" (1.80mm) |
Size / Dimension: | 0.390" L x 0.220" W (9.91mm x 5.59mm) |
Supplier Device Package: | -- |
Package / Case: | 14-SOIC (0.220", 5.59mm Width) |
Mounting Type: | Surface Mount |
Applications: | -- |
Operating Temperature: | -55°C ~ 125°C |
Temperature Coefficient: | ±100ppm/°C |
Power Per Element: | 200mW |
Series: | 768 |
Resistor-Ratio-Drift: | -- |
Resistor Matching Ratio: | -- |
Number of Resistors: | 7 |
Tolerance: | ±2% |
Resistance (Ohms): | 330 |
Circuit Type: | Isolated |
Part Status: | Obsolete |
Packaging: | Tube |
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html>Resistor Networks, Arrays
A 768143331G, or general-purpose resistor network, is a passive two-terminal electronic component that is used to provide a uniform impedance distribution between several points in an electronic system. It is made up of an array of resistors connected together in a particular network configuration.
Resistor networks come in a wide variety of configurations including, but not limited to, two-terminal, three-terminal, four-terminal, and five-terminal devices. They can also be constructed using various types of resistive materials such as carbon, metal, and ceramic, as well as multiple combinations of resistors to provide additional impedance values.
Application Field
Resistor networks are used in a wide variety of applications including the production of uniform power distribution across a circuit board, signal filtering, and amplification. They can also be used in combination with capacitors and active components to form low-pass, high-pass, band-pass, and notch filters. In addition, they can be used as a fast, low-impedance connection between high-impedance components such as remote sensing systems and electromechanical devices.
Resistor networks are also commonly used in the production of analog computers, mobile phones, and various other electronic devices where adjustable current and voltage sources are needed. In addition, they can be used in a range of industrial applications including process control, SCADA systems, and machine vision systems.
Working Principle
The working principle of a resistor network is based on the concept of impedance. Impedance is defined as the ratio of the voltage drop across a component to the current that flows through it. In a resistor network, the resistances of the individual resistors are combined in such a way that the total impedance of the network is equal to the sum of the individual impedances. This arrangement ensures that the same voltage is produced across each of the resistors, thus providing a uniform impedance distribution.
Resistor networks are typically used in combination with other passive and active components in order to create circuits with specific voltage, current, and power needs. For instance, in analog computers, they are often used in conjunction with variable capacitors, transistors, and integrated circuits in order to produce a wide range of analog signals.
Conclusion
Resistor networks are a versatile and reliable type of electronic component that can be used in many different applications. They are highly efficient, easy to use, and can provide a uniform impedance distribution across numerous points. In addition, they can be used in combination with capacitors and other active components in order to create low-pass, high-pass, band-pass, and notch filters, as well as adjustable current and voltage sources. Despite their many advantages, resistor networks can be difficult to use correctly and, as such, require some amount of experience and expertise in order to get the best performance out of them.