The RVG4H01-104VM-TC is a thermistor manufactured by Murata Electronics North America, designed for temperature sensing and compensation in various electronic applications. It is characterized by its reliable performance and compact size, making it suitable for use in devices requiring precise temperature monitoring and control. This thermistor is particularly useful in applications where space is limited but accurate temperature readings are essential.

Applications

• Temperature compensation in electronic circuits
• Temperature sensing in consumer electronics
• Temperature monitoring in automotive systems
• Temperature control in industrial equipment
• Overheat protection in power supplies

Features

• High-accuracy temperature sensing
• Excellent temperature sensitivity
• Small form factor for space-constrained applications
• Wide operating temperature range
• Fast response time to temperature variations
• Highly stable and reliable performance
• Tape and reel packaging for automated assembly

Benefits

• Enables precise temperature control for improved system performance.
• Provides reliable temperature sensing for accurate data.
• Allows integration into compact devices due to its small size.
• Suitable for use in diverse environments with its wide temperature range.
• Facilitates real-time temperature adjustments with its fast response time.
• Ensures long-term operational stability with its durable construction.
• Reduces manufacturing costs through automated assembly.

Additional Details

The RVG4H01-104VM-TC is an NTC (Negative Temperature Coefficient) thermistor, indicating that its resistance decreases as temperature increases. Its resistance value is 100kΩ at 25°C. The TC suffix signifies that the component is supplied on tape and reel for automated pick and place during PCB assembly. This thermistor is optimized for applications that require a high degree of temperature sensing accuracy and stability. It is commonly used to protect circuits from overheating and to ensure optimal performance across different operating temperatures.