Allicdata Part #: | H11N3FR2M-ND |
Manufacturer Part#: |
H11N3FR2M |
Price: | $ 0.00 |
Product Category: | Isolators |
Manufacturer: | ON Semiconductor |
Short Description: | OPTOISO 4.17KV OPN COLL 6SMD |
More Detail: | Logic Output Optoisolator 5MHz Open Collector 4170... |
DataSheet: | H11N3FR2M Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Series: | -- |
Packaging: | Tape & Reel (TR) |
Part Status: | Obsolete |
Number of Channels: | 1 |
Inputs - Side 1/Side 2: | 1/0 |
Voltage - Isolation: | 4170Vrms |
Common Mode Transient Immunity (Min): | -- |
Input Type: | DC |
Output Type: | Open Collector |
Current - Output / Channel: | 50mA |
Data Rate: | 5MHz |
Propagation Delay tpLH / tpHL (Max): | 330ns, 330ns |
Rise / Fall Time (Typ): | 7.5ns, 12ns |
Voltage - Forward (Vf) (Typ): | 1.4V |
Current - DC Forward (If) (Max): | 30mA |
Voltage - Supply: | 4 V ~ 15 V |
Operating Temperature: | -40°C ~ 85°C |
Mounting Type: | Surface Mount |
Package / Case: | 6-SMD, Gull Wing |
Supplier Device Package: | 6-SMD |
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 an important technology in the field of electric isolation. H11N3FR2M technology is one common application, and it utilizes a combination of optical, electrical, and even magnetic structures to break electric circuits between two points. A better understanding of the H11N3FR2M technology and its working principle can help engineers and researchers make more applications of this technology.
The H11N3FR2M technology generally uses a photosensitive semiconductor device with an output transistor as its core device. Connecting the source, drain, gate, and LED electrodes moves the photoelectric conversion signal to the output directly. It is often used to drive the infrared LEDs for transmission isolation when the optical serial port or transmission module is connected.
Specifically, H11N3FR2M technology works by converting electrical signals into optical signals for isolation transmission. The electrical input is transmitted to the infrared LED, which emits the light signal through the output interface. Simultaneously, the photo diode receives the optical information and the current converted by the photoelectric device is then amplified to the buffer output. In other words, the output generated by the buffer amplifier is electrically isolated from the input.
In the past, it is difficult to transfer high-frequency or low-voltage signals due to the limitations of the signal transmission methond in electrical isolation technology. However, with the H11N3FR2M technology, the voltage between the two sides can be as high as 5000V and the frequency up to 500KHz, making it much more efficient and reliable. Moreover, its response time is about 50 micro seconds, which is much faster than other isolation technologies.
From the perspective of topology, due to its combination of optical and electrical components, H11N3FR2M technology has a lower electromagnetic interference than other electric isolation technologies. Moreover, due to the fact that this technology does not directly conduct electricity, it significantly reduces pyroelectric noise and thus further improves the accuracy and reliability of the system.
Besides, the H11N3FR2M technology is also more compact and lightweight, and it is more suitable for applications with small sizes or tight space requirements. Furthermore, its low power consumption also means it has a longer use life.
H11N3FR2M technology has been widely used in many applications, including power supplies, industrial automation, and automotive electronics. For example, it is used to increase the reliability and accuracy of the power transmission in the industrial control systems and for the isolation of data transmission in medical electronics. The H11N3FR2M technology is also increasingly utilized in automotive control systems, such as the power window control systems and door opening control systems.
In conclusion, H11N3FR2M technology is an essential technology for electric isolation. Its effectiveness, accuracy, and reliability make it ideal for many applications. By understanding its working principle and advantages, engineers and researchers can make more applications of this technology and further improve the quality and efficiency of their products and systems.
The specific data is subject to PDF, and the above content is for reference
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