Category: Integrated Circuit (IC)
Use: SN65LVDS390PWR is a low-voltage differential signaling (LVDS) serializer/deserializer (SerDes) IC. It is commonly used for high-speed data transmission in various applications such as video interfaces, communication systems, and industrial automation.
Characteristics: - LVDS technology enables high-speed data transfer with low power consumption. - Supports data rates up to 400 Mbps. - Provides robust noise immunity and common-mode rejection. - Operates at a low supply voltage of 3.3V.
Package: SN65LVDS390PWR is available in a small form factor package known as TSSOP-16 (Thin Shrink Small Outline Package). This package offers compactness and ease of integration into electronic circuits.
Essence: The essence of SN65LVDS390PWR lies in its ability to convert parallel data into serial data and vice versa using LVDS signaling. This allows for efficient and reliable transmission of high-speed digital signals over long distances.
Packaging/Quantity: SN65LVDS390PWR is typically sold in reels or tubes containing a quantity of 250 or 300 units per package.
The pin configuration of SN65LVDS390PWR is as follows:
Pin 1: VCC
Pin 2: GND
Pin 3: CLKIN
Pin 4: CLKOUT
Pin 5: DATAIN0
Pin 6: DATAOUT0
Pin 7: DATAIN1
Pin 8: DATAOUT1
Pin 9: DATAIN2
Pin 10: DATAOUT2
Pin 11: DATAIN3
Pin 12: DATAOUT3
Pin 13: DATAIN4
Pin 14: DATAOUT4
Pin 15: DATAIN5
Pin 16: DATAOUT5
Advantages: - High-speed data transmission capability. - Low power consumption. - Robust noise immunity. - Compact package size for easy integration.
Disadvantages: - Limited to LVDS interface compatibility. - Requires additional components for complete system implementation.
SN65LVDS390PWR works on the principle of LVDS signaling. It uses differential voltage levels to transmit digital data over twisted-pair copper cables. The serializer converts parallel data inputs into a serialized LVDS signal, while the deserializer performs the reverse operation. This enables efficient transmission of high-speed data with low power consumption and noise immunity.
SN65LVDS390PWR finds applications in various fields, including:
Some alternative models to SN65LVDS390PWR that offer similar functionality are:
These alternative models can be considered based on specific requirements and design constraints.
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Sure! Here are 10 common questions and answers related to the application of SN65LVDS390PWR in technical solutions:
Q: What is SN65LVDS390PWR? A: SN65LVDS390PWR is a low-voltage differential signaling (LVDS) serializer/deserializer (SerDes) IC used for high-speed data transmission.
Q: What is the maximum data rate supported by SN65LVDS390PWR? A: SN65LVDS390PWR supports a maximum data rate of 400 Mbps.
Q: What is the operating voltage range of SN65LVDS390PWR? A: SN65LVDS390PWR operates within a voltage range of 3.0V to 3.6V.
Q: Can SN65LVDS390PWR be used for point-to-point communication? A: Yes, SN65LVDS390PWR is commonly used for point-to-point communication between devices.
Q: Does SN65LVDS390PWR support bidirectional communication? A: No, SN65LVDS390PWR is a unidirectional SerDes IC and does not support bidirectional communication.
Q: What is the typical output swing of SN65LVDS390PWR? A: The typical output swing of SN65LVDS390PWR is around 350 mV.
Q: Can SN65LVDS390PWR be used for long-distance data transmission? A: Yes, SN65LVDS390PWR is suitable for long-distance data transmission due to its LVDS technology, which provides noise immunity and low power consumption.
Q: What is the recommended termination scheme for SN65LVDS390PWR? A: SN65LVDS390PWR requires a 100-ohm differential termination resistor at the receiver end.
Q: Can SN65LVDS390PWR be used in automotive applications? A: Yes, SN65LVDS390PWR is qualified for automotive applications and can withstand harsh operating conditions.
Q: What are some typical applications of SN65LVDS390PWR? A: SN65LVDS390PWR is commonly used in applications such as video transmission, high-speed data communication, and industrial automation systems.
Please note that these answers are general and may vary depending on specific design requirements and application scenarios.