Allicdata Part #: | H11N1TM-ND |
Manufacturer Part#: |
H11N1TM |
Price: | $ 0.00 |
Product Category: | Isolators |
Manufacturer: | ON Semiconductor |
Short Description: | OPTOISO 4.17KV OPN COLL 6DIP |
More Detail: | Logic Output Optoisolator 5MHz Open Collector 4170... |
DataSheet: | H11N1TM Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Data Rate: | 5MHz |
Supplier Device Package: | 6-DIP |
Package / Case: | 6-DIP (0.400", 10.16mm) |
Mounting Type: | Through Hole |
Operating Temperature: | -40°C ~ 85°C |
Voltage - Supply: | 4 V ~ 15 V |
Current - DC Forward (If) (Max): | 30mA |
Voltage - Forward (Vf) (Typ): | 1.4V |
Rise / Fall Time (Typ): | 7.5ns, 12ns |
Propagation Delay tpLH / tpHL (Max): | 330ns, 330ns |
Series: | -- |
Current - Output / Channel: | 50mA |
Output Type: | Open Collector |
Input Type: | DC |
Common Mode Transient Immunity (Min): | -- |
Voltage - Isolation: | 4170Vrms |
Inputs - Side 1/Side 2: | 1/0 |
Number of Channels: | 1 |
Part Status: | Obsolete |
Packaging: | Tube |
Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us: sales@allicdata.com
Optoisolators - Logic Output is a useful application of the H11N1TM technology for computer engineering. The application of the H11N1TM technology to Optoisolators - Logic Output enables computer engineers to protect signals from environmental or electrical interference within the circuit board. This technology is employed in applications where low power and high speed output logic are required. It is also used for signal transmission in digital systems due to its inherent features, such as high isolation voltage, low impedance, and fast signal response.
The working principle of H11N1TM for Optoisolators - Logic Output relies on the usage of integrated optical signal processing and a combination of isolator and LED. The optical isolator terminates the input signal and provides isolation between the digital and analog circuitry by using an optical shutter or transmissive shielding. The signal is then fed into an LED, which is electrically isolated from the active transistorized circuit and acts as an amplifier for the signal.
Once the signal has been amplified, it is then routed through a current limiter to ensure the contents of the circuit board are not damaged. After passing through the current limiter, it is then directed into a baseband signal with a preset amplitude. Finally, the signal is ready for output to the logic circuit. It is then amplified, filtered, and passed through another isolator stage to further reduce interference.
The advantages of using H11N1TM for Optoisolators - Logic Output include its higher speed, flexibility, and lower cost compared to more traditional optical signal processing techniques like coaxial cables, fiber optics, or waveguides. It also offers better EMI/RFI protection due to its low impedance and fast signal response. Furthermore, it offers higher protection against voltage overshoot due to its low input voltage requirements.
In addition, H11N1TM Optoisolators - Logic Output has other advantages when compared to traditional techniques. For example, it has better accuracy and can handle higher voltage levels, leading to fewer false starts or errors. It also offers improved output accuracy due to the fact that a wider range of input signals can be processed. Furthermore, it is not subject to mechanical degradation or drift due to its solid-state nature.
Overall, the H11N1TM technology is a very useful tool for computer engineers, and many applications can benefit from its implementation. It offers higher speed, greater flexibility, better EMI/RFI protection, improved accuracy, and better voltage overshoot protection, all of which make it an ideal choice for use in Optoisolators - Logic Output. It also offers lower cost and increased reliability, making it an ideal choice for applications requiring both optical signal processing and electrical isolation.
The specific data is subject to PDF, and the above content is for reference
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