Allicdata Part #: | SOMC24.3KGTR-ND |
Manufacturer Part#: |
SOMC160324K3FEA |
Price: | $ 0.56 |
Product Category: | Resistors |
Manufacturer: | Vishay Dale |
Short Description: | RES ARRAY 8 RES 24.3K OHM 16SOIC |
More Detail: | 24.3k Ohm ±1% 160mW Power Per Element Isolated 8 R... |
DataSheet: | SOMC160324K3FEA Datasheet/PDF |
Quantity: | 1000 |
2000 +: | $ 0.50375 |
6000 +: | $ 0.49783 |
Series: | SOMC |
Packaging: | Tape & Reel (TR) |
Part Status: | Active |
Circuit Type: | Isolated |
Resistance (Ohms): | 24.3k |
Tolerance: | ±1% |
Number of Resistors: | 8 |
Resistor Matching Ratio: | -- |
Resistor-Ratio-Drift: | -- |
Number of Pins: | 16 |
Power Per Element: | 160mW |
Temperature Coefficient: | ±100ppm/°C |
Operating Temperature: | -55°C ~ 150°C |
Applications: | -- |
Mounting Type: | Surface Mount |
Package / Case: | 16-SOIC (0.220", 5.59mm Width) |
Supplier Device Package: | -- |
Size / Dimension: | 0.440" L x 0.220" W (11.18mm x 5.59mm) |
Height - Seated (Max): | 0.090" (2.29mm) |
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.Resistor Networks, Arrays consist of numerous electronic components connected in specific arrangements for various applications. One such application is the SOMC160324K3FEA, an implementation of resistor networks and arrays. In this article, we will discuss the application fields and working principles associated with the SOMC160324K3FEA.
SOMC160324K3FEA is part of the SOMC series designed by SUNNY OPTICAL TECHNOLOGIES CORPORATION, and is a merging of resistor networks and arrays for use in various fields. The SOMC160324K3FEA integrates resistor networks and arrays in a durable and reliable way, making it perfect for audio and industrial applications. It can also be used in power electronic systems, wireless communication systems, and home appliances.
The primary function of the SOMC160324K3FEA is to provide an interface between components in a circuit. It achieves this by evenly distributing the load over the resistors. The components in the networks and arrays are arranged in a specific pattern, such that the flow of current is regulated and any potential build-up of current is minimized. This helps reduce the amount of energy loss in the circuit, thereby increasing the efficiency of the system.
The working principle of SOMC160324K3FEA is based on the concept of impedance. Impedance is the measure of the opposition to the flow of current in an electrical circuit. This impedance is created by the resistance of the components in the networks and arrays. The impedance of each component in the network is calculated to determine the optimal arrangement for the system. In addition to this, a range of materials, such as metals and polymers, have been used to create components with higher impedance than traditional components.
Moreover, the arrangement of the resistors in the networks and arrays also affects the performance of the SOMC160324K3FEA. For example, the spacing of the resistors can affect the voltage across the components. This is because when the spacing of the resistors decreases, the resistance of the whole network increases, leading to an increase in voltage across the components. Similarly, when the spacing of the resistors increases, the resistance of the whole network decreases, leading to a decrease in voltage across the components.
Furthermore, the operational temperature and climate of the environment plays a role in determining the performance of the SOMC160324K3FEA. The component materials used in the networks and arrays have different temperature coefficients, meaning they have different resistance values under different temperatures. This is important to consider when choosing the arrangement and components for the networks and arrays. In addition to this, certain components may be more susceptible to environmental factors, such as humidity, and should be accounted for when designing networks and arrays.
In conclusion, the SOMC160324K3FEA is an ideal solution for applications in audio and industrial fields. Its working principle is based on impedance, with the arrangement of its components playing an important role in its performance. Factors such as temperature and climate also play a role in determining the performance of the SOMC160324K3FEA. Therefore, it is important for engineers to be aware of these factors when designing networks and arrays, and employing the SOMC160324K3FEA.
The specific data is subject to PDF, and the above content is for reference
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SOMC140122K0GEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 22K OHM ... |
SOMC14012K70GEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 2.7K OHM... |
SOMC1401330RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 330 OHM ... |
SOMC140133K0GEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 33K OHM ... |
SOMC14013K30GEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 3.3K OHM... |
SOMC1401430RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 430 OHM ... |
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SOMC1401560RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 560 OHM ... |
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SOMC14015K60GEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 5.6K OHM... |
SOMC1401680RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 680 OHM ... |
SOMC1403100RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 7 RES 100 OHM 1... |
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SOMC1403150KGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 7 RES 150K OHM ... |
SOMC1403150RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 7 RES 150 OHM 1... |
SOMC1403180RGEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 7 RES 180 OHM 1... |
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SOMC140110K0JEA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 13 RES 10K OHM ... |
RES NTWRK 18 RES 47 OHM 36LBGA47 Ohm 1% ...
RES NTWRK 32 RES 56 OHM 36LBGA56 Ohm 1% ...
RES ARRAY 4 RES 39 OHM 120639 Ohm 5% 62....
RES ARRAY 4 RES 43 OHM 080443 Ohm 5% 62....
RES ARRAY 4 RES 120 OHM 0804120 Ohm 5% 6...
RES ARRAY 2 RES 300 OHM 0606300 Ohm 5% 6...