| Allicdata Part #: | CSC09A013K30GPA-ND |
| Manufacturer Part#: |
CSC09A013K30GPA |
| Price: | $ 0.45 |
| Product Category: | Resistors |
| Manufacturer: | Vishay Dale |
| Short Description: | RES ARRAY 8 RES 3.3K OHM 9SIP |
| More Detail: | 3.3k Ohm ±2% 200mW Power Per Element Bussed 8 Resi... |
| DataSheet: | CSC09A013K30GPA Datasheet/PDF |
| Quantity: | 1000 |
| 2000 +: | $ 0.40277 |
| 5000 +: | $ 0.39803 |
| Number of Pins: | 9 |
| Height - Seated (Max): | 0.195" (4.95mm) |
| Size / Dimension: | 0.890" L x 0.098" W (22.61mm x 2.49mm) |
| Supplier Device Package: | 9-SIP |
| Package / Case: | 9-SIP |
| Mounting Type: | Through Hole |
| Applications: | -- |
| Operating Temperature: | -55°C ~ 125°C |
| Temperature Coefficient: | ±100ppm/°C |
| Power Per Element: | 200mW |
| Series: | CSC |
| Resistor-Ratio-Drift: | ±50 ppm/°C |
| Resistor Matching Ratio: | -- |
| Number of Resistors: | 8 |
| Tolerance: | ±2% |
| Resistance (Ohms): | 3.3k |
| Circuit Type: | Bussed |
| Part Status: | Active |
| Packaging: | Bulk |
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CSC09A013K30GPA is a type of resistor network which is typically used for reliable power control and protection products. It is a component that is used for setting load current for semiconductor protection and control applications and is widely used in various areas, including industrial, military, automotive, telecommunications, aerospace and consumer electronics. The resistor network is composed of multiple components such as resistors, transistors, capacitors etc. Depending on the application, it can provide simple voltage or power regulation, or complex protection functions. This article explains the working principle of CSC09A013K30GPA Resistor Network and the applications it is used for.
The CSC09A013K30GPA Resistor Network is a three-terminal device consisting of five n-channel polysilicon FETs (Field-Effect Transistors) which can be used to manage the flow of power or current from one part of the network to another. It features a built-in resistor network to limit the power dissipation and ensure that the device does not become a thermal risk. This resistor network also helps to spread the heat generated by the devices such as transistors and thereby reduces EMI (Electromagnetic Interference). This type of resistor network is also created using three resistors connected in parallel that can handle higher power than three resistors connected in series.
When using this resistor network, it is important to understand its working principle in order to ensure optimum performance. The main working principle behind the CSC09A013K30GPA Resistor Network is simple which involves the application of a constant voltage or current in the resistor network. This is done by applying a voltage or current at the resistor network\'s input terminal which is then distributed among the resistors by the interconnected connected FETs. By controlling the FETs, the current and voltage of the device can be accurately managed, allowing for precise control and protection of the circuits.
CSC09A013K30GPA Resistor Network can be used in a wide range of applications which includes avionics, power management, automotive, medical and consumer electronics. It can be used to limit the current and voltage in order to protect the components of a circuit from overcurrent and overvoltage. It is also used to regulate the power in a process, for example in an automated engine management system, allowing for safe and efficient operation. Other applications include stabilizing power supplies, regulating the output of DC-DC Converters and providing load protection and isolation for RF designs.
In conclusion, CSC09A013K30GPA Resistor Network is a reliable device which is used to provide protection and control for a variety of applications. It features a built-in resistor network which helps to distribute the power dissipated by the integrated components and reduce EMI. It also allows for precise control and protection of the circuitry by controlling the FETs. The working principle behind the CSC09A013K30GPA Resistor Network involves applying a constant voltage or current at the input of the device which is then distributed among the resistors. This resistor network can be used in many applications such as avionics, power management, automotive, medical and consumer electronics.
The specific data is subject to PDF, and the above content is for reference
| Part Number | Manufacturer | Price | Quantity | Description |
|---|
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| CSC06A0322R0GPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 3 RES 22 OHM 6S... |
| CSC06A03270RGPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 3 RES 270 OHM 6... |
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| CSC05A011K00GPA | Vishay Dale | 0.42 $ | 1000 | RES ARRAY 4 RES 1K OHM 5S... |
| CSC05A01330RGPA | Vishay Dale | 0.42 $ | 1000 | RES ARRAY 4 RES 330 OHM 5... |
| CSC06A01470RGPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 5 RES 470 OHM 6... |
| CSC08A0310K0GPA | Vishay Dale | -- | 1000 | RES ARRAY 4 RES 10K OHM 8... |
| CSC08A03820RGPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 4 RES 820 OHM 8... |
| CSC04A03560RGEK | Vishay Dale | 0.21 $ | 1000 | RES ARRAY 2 RES 560 OHM 4... |
| CSC08A03560RGEK | Vishay Dale | 0.21 $ | 1000 | RES ARRAY 4 RES 560 OHM 8... |
| CSC09A013K30GPA | Vishay Dale | 0.45 $ | 1000 | RES ARRAY 8 RES 3.3K OHM ... |
| CSC06A0122K0GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 22K OHM 6... |
| CSC09A011M00GPA | Vishay Dale | 0.45 $ | 1000 | RES ARRAY 8 RES 1M OHM 9S... |
| CSC06A01270RGPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 5 RES 270 OHM 6... |
| CSC08A031K50GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 4 RES 1.5K OHM ... |
| CSC09A0122K0GEK | Vishay Dale | 0.29 $ | 1000 | RES ARRAY 8 RES 22K OHM 9... |
| CSC06A0368K0GPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 3 RES 68K OHM 6... |
| CSC09A01510RGPA | Vishay Dale | 0.45 $ | 1000 | RES ARRAY 8 RES 510 OHM 9... |
| CSC08B031K00GPA | Vishay Dale | 0.65 $ | 1000 | RES ARRAY 4 RES 1K OHM 8S... |
| CSC06A0147K0GEK | Vishay Dale | 0.16 $ | 1000 | RES ARRAY 5 RES 47K OHM 6... |
| CSC06A0110K0GEK | Vishay Dale | 0.41 $ | 3794 | RES ARRAY 5 RES 10K OHM 6... |
| CSC08A01330RGPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 7 RES 330 OHM 8... |
| CSC08A0368R0GPA | Vishay Dale | 0.44 $ | 1000 | RES ARRAY 4 RES 68 OHM 8S... |
| CSC09A0110K0FPA | Vishay Dale | 0.52 $ | 1000 | RES ARRAY 8 RES 10K OHM 9... |
| CSC06A0110K0GPA | Vishay Dale | 0.47 $ | 1000 | RES ARRAY 5 RES 10K OHM 6... |
| CSC08A031K00GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 4 RES 1K OHM 8S... |
| CSC04A0133K0GPA | Vishay Dale | 0.41 $ | 1000 | RES ARRAY 3 RES 33K OHM 4... |
| CSC09B014K70GPA | Vishay Dale | 0.69 $ | 1000 | RES ARRAY 8 RES 4.7K OHM ... |
| CSC08A01330RGEK | Vishay Dale | 0.5 $ | 3770 | RES ARRAY 7 RES 330 OHM 8... |
| CSC06A0127K0GPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 5 RES 27K OHM 6... |
| CSC06A01390RGPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 5 RES 390 OHM 6... |
| CSC06A013K30GPA | Vishay Dale | 0.43 $ | 1000 | RES ARRAY 5 RES 3.3K OHM ... |
| CSC08A033K30GPA | Vishay Dale | 0.48 $ | 1000 | RES ARRAY 4 RES 3.3K 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...
CSC09A013K30GPA Datasheet/PDF