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SN65LVDT388ADBTR
Product Overview
- Category: Integrated Circuit (IC)
- Use: LVDS Transceiver
- Characteristics:
- High-speed data transmission
- Low voltage differential signaling
- Robust noise immunity
- Wide operating temperature range
- Package: TSSOP-38
- Essence: Transceiver for LVDS communication
- Packaging/Quantity: Tape and Reel, 2500 units per reel
Specifications
- Supply Voltage Range: 3.3V ±10%
- Operating Temperature Range: -40°C to +85°C
- Data Rate: Up to 400 Mbps
- Number of Channels: 8
- Input Common-Mode Voltage Range: -1V to +2V
- Output Voltage Swing: 350mV (minimum)
- Propagation Delay: 1.5ns (typical)
Pin Configuration
The SN65LVDT388ADBTR has a total of 38 pins. The pin configuration is as follows:
- VCC
- GND
- AIN0
- AIN1
- AIN2
- AIN3
- AIN4
- AIN5
- AIN6
- AIN7
- BOUT0
- BOUT1
- BOUT2
- BOUT3
- BOUT4
- BOUT5
- BOUT6
- BOUT7
- BOUT8
- BOUT9
- BOUT10
- BOUT11
- BOUT12
- BOUT13
- BOUT14
- BOUT15
- BOUT16
- BOUT17
- BOUT18
- BOUT19
- BOUT20
- BOUT21
- BOUT22
- BOUT23
- BOUT24
- BOUT25
- BOUT26
- BOUT27
Functional Features
- High-speed data transmission: The SN65LVDT388ADBTR supports data rates up to 400 Mbps, making it suitable for applications requiring fast communication.
- Low voltage differential signaling (LVDS): LVDS is a signaling technique that provides high noise immunity and low power consumption, making it ideal for long-distance data transmission.
- Robust noise immunity: The transceiver has built-in noise filtering mechanisms to ensure reliable data transmission in noisy environments.
- Wide operating temperature range: With an operating temperature range of -40°C to +85°C, the SN65LVDT388ADBTR can be used in various industrial and automotive applications.
Advantages and Disadvantages
Advantages: - High-speed data transmission capability - Robust noise immunity - Wide operating temperature range
Disadvantages: - Limited number of channels (8 channels)
Working Principles
The SN65LVDT388ADBTR is a transceiver designed for LVDS communication. It uses low voltage differential signaling to transmit data between devices. LVDS employs a differential voltage across two wires to represent digital information. This differential signaling technique provides high noise immunity and allows for longer cable lengths compared to single-ended signaling.
The transceiver receives LVDS signals on the AIN pins and converts them into parallel CMOS/TTL outputs on the BOUT pins. Similarly, it accepts parallel CMOS/TTL inputs on the BOUT pins and converts them into LVDS signals on the AIN pins. This bidirectional functionality enables seamless communication between LVDS-compatible devices.
Detailed Application Field Plans
The SN65LVDT388ADBTR is commonly used in various applications, including:
- Industrial Automation: The transceiver is used in industrial automation systems for high-speed data transmission between sensors, actuators, and control units.
- Automotive Electronics: It finds application in automotive electronics for communication between different modules, such as engine control units, infotainment systems, and body control modules.
- Medical Equipment: The SN65LVDT388ADBTR is utilized in medical equipment for reliable data transmission between devices, ensuring accurate monitoring and control.
- Communication Systems: It is employed in communication systems, such as routers and switches, to enable high-speed data transfer between network components.
Detailed and Complete Alternative Models
- SN65LVDT388A
- SN65LVDT388B
- SN65LVDT388C
- SN65LVDT388D
- SN65LVDT388E
These alternative models offer similar functionality and characteristics to the SN65LVDT388ADBTR, providing options for different design requirements and preferences.
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Wymień 10 typowych pytań i odpowiedzi związanych z zastosowaniem SN65LVDT388ADBTR w rozwiązaniach technicznych
Sure! Here are 10 common questions and answers related to the application of SN65LVDT388ADBTR in technical solutions:
Q: What is the SN65LVDT388ADBTR? A: The SN65LVDT388ADBTR is a high-speed LVDS (Low Voltage Differential Signaling) driver and receiver designed for applications requiring high data rates and low power consumption.
Q: What are the key features of SN65LVDT388ADBTR? A: Some key features include wide operating voltage range, low power consumption, high data rates up to 400 Mbps, and compatibility with LVDS standards.
Q: What are some typical applications of SN65LVDT388ADBTR? A: It is commonly used in applications such as industrial automation, motor control systems, communication interfaces, and high-speed data transmission.
Q: How does SN65LVDT388ADBTR achieve high data rates? A: SN65LVDT388ADBTR uses LVDS technology, which provides high-speed data transmission by using differential signaling and low voltage swings.
Q: Can SN65LVDT388ADBTR operate at different voltage levels? A: Yes, it can operate at various voltage levels ranging from 3.3V to 5V, making it compatible with different system requirements.
Q: Does SN65LVDT388ADBTR support bidirectional communication? A: No, SN65LVDT388ADBTR is a unidirectional driver and receiver, meaning it can only transmit or receive signals in one direction at a time.
Q: What is the maximum cable length supported by SN65LVDT388ADBTR? A: The maximum cable length depends on factors like data rate, cable quality, and noise environment. Generally, it can support cable lengths up to several meters.
Q: Does SN65LVDT388ADBTR have built-in protection features? A: Yes, it has built-in ESD (Electrostatic Discharge) protection and overvoltage protection, which help safeguard the device from damage.
Q: Can SN65LVDT388ADBTR be used in harsh industrial environments? A: Yes, SN65LVDT388ADBTR is designed to operate reliably in harsh industrial environments with wide temperature ranges and high noise immunity.
Q: Are there any evaluation boards or reference designs available for SN65LVDT388ADBTR? A: Yes, Texas Instruments provides evaluation boards and reference designs that can help users quickly prototype and evaluate the performance of SN65LVDT388ADBTR in their applications.
Please note that these answers are general and may vary depending on specific application requirements. It is always recommended to refer to the datasheet and consult with the manufacturer for detailed information.