Allicdata Part #: | CSC560B-ND |
Manufacturer Part#: |
CSC04A03560RGPA |
Price: | $ 0.45 |
Product Category: | Resistors |
Manufacturer: | Vishay Dale |
Short Description: | RES ARRAY 2 RES 560 OHM 4SIP |
More Detail: | 560 Ohm ±2% 300mW Power Per Element Isolated 2 Res... |
DataSheet: | CSC04A03560RGPA Datasheet/PDF |
Quantity: | 1000 |
2000 +: | $ 0.40581 |
6000 +: | $ 0.40104 |
Series: | CSC |
Packaging: | Bulk |
Part Status: | Active |
Circuit Type: | Isolated |
Resistance (Ohms): | 560 |
Tolerance: | ±2% |
Number of Resistors: | 2 |
Resistor Matching Ratio: | -- |
Resistor-Ratio-Drift: | ±50 ppm/°C |
Number of Pins: | 4 |
Power Per Element: | 300mW |
Temperature Coefficient: | ±100ppm/°C |
Operating Temperature: | -55°C ~ 125°C |
Applications: | -- |
Mounting Type: | Through Hole |
Package / Case: | 4-SIP |
Supplier Device Package: | 4-SIP |
Size / Dimension: | 0.390" L x 0.098" W (9.91mm x 2.49mm) |
Height - Seated (Max): | 0.195" (4.95mm) |
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The CSC04A03560RGPA resistor network is a type of electronic component that enables the design of processor circuits. It consists of an integrated set of resistors connected in a specified arrangement to achieve a desired electrical effect. The component is available as a single package and in configurations suitable for both surface mount and through-hole mounting.
In most cases, the CSC04A03560RGPA is designed to provide an electrical bridge between two otherwise isolated circuits or to provide a level-shifting mechanism, the latter being particularly useful when used in analog-digital conversion. It is often used in complex systems such as televisions, computers, and other devices, and allows for easy installation of processors.
The working principle of the CSC04A03560RGPA is based on the simple concept of supply and ground connections. The resistor network is configured in such a way that limited voltage is applied to separate ground connections. The current passing through the resistor network is determined by the supply voltage plus the applied ground voltage. This voltage differential between the supply and ground connections determines the overall current of the resistor network.
In analog applications, the CSC04A03560RGPA is used to create voltage dividers. This is a form of voltage regulation in which the appropriate amount of voltage is supplied to a given circuit from a larger supply. The resistor network is designed in such a way that the desired amount of voltage is maintained without having to apply additional components or circuitry.
In digital applications, the CSC04A03560RGPA is used to create timer circuits. This is an important function in computer applications because it allows the processor to determine the timing of certain operations and control the speed at which individual components in the system operate. The resistor network is set up to provide an accurate and consistent amount of time which will be used by the processor in its calculations.
The CSC04A03560RGPA is also used in power distribution applications. This type of circuit helps maintain a constant and reliable source of power to multiple components in a system. The resistors are positioned in a parallel configuration in order to increase the number of current paths and reduce power losses from each component.
Lastly, the CSC04A03560RGPA can be used in signal processing applications. This is done by positioning the resistors in a differential configuration, which is then connected to an operational amplifier. Here, the differential signal is amplified in order to improve the accuracy and precision of the signal processing operations.
In conclusion, the CSC04A03560RGPA is a versatile component that has a variety of applications in the design of processor circuits. It is used not only in analog and digital circuits, but also in power distribution and signal processing applications. It is available in a variety of configurations suitable for both surface mount and through-hole mounting. Knowing the working principles of this resistor network, engineers can design faster and more efficient processor circuits.
The specific data is subject to PDF, and the above content is for reference
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CSC06A01100KGPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 100K OHM ... |
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CSC06A0122K0GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 22K OHM 6... |
CSC06A0147K0GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 47K OHM 6... |
CSC06A014K70GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 4.7K OHM ... |
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CSC06A03100KGPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 3 RES 100K OHM ... |
CSC06A0310K0GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 3 RES 10K OHM 6... |
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CSC07A0110K0GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 6 RES 10K OHM 7... |
CSC07A0147K0GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 6 RES 47K OHM 7... |
CSC08A01100KGPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 7 RES 100K OHM ... |
CSC08A0110K0GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 7 RES 10K OHM 8... |
CSC08A011K00GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 7 RES 1K OHM 8S... |
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...