The RK7002 FD5T116 is a small signal N-channel MOSFET from Rohm Semiconductor designed for low voltage, low current switching applications. This MOSFET offers fast switching speeds and is commonly used in portable devices and other low-power electronic circuits.

Applications

• Small Signal Switching: Used in circuits that require efficient switching of small signals.
• Load Switching: Used as a switch to control power to small loads.
• Inverter Circuits: Used in low-power inverter applications.
• Level Shifting: Used for voltage level shifting in digital circuits.

Features

• N-Channel MOSFET: Easy to drive with digital logic levels.
• Low On-Resistance: Minimizes power loss and enhances efficiency.
• Fast Switching Speed: Enables rapid switching operations.
• Surface Mount Package: Small package size allows for high-density board layouts.
• RoHS Compliant: Environmentally friendly, compliant with RoHS standards.

Benefits

• Efficient Switching: Reduces power consumption in switching applications.
• Simple Drive: Easy to interface with digital control signals.
• Compact Size: Ideal for portable and miniaturized devices.
• Reliable Performance: Ensures consistent and reliable operation.

Additional Details

The RK7002 FD5T116 has a low threshold voltage, typically around 1 to 2 volts, making it suitable for low voltage logic circuits. The maximum drain-source voltage (Vds) is generally around 60V, and the drain current (Id) capability is limited to a few hundred milliamperes depending on the specific operating conditions and package thermal characteristics. It comes in a small surface mount package, allowing for high-density layouts on PCBs. The low on-resistance helps minimize power dissipation, contributing to improved energy efficiency and reduced heat generation. For detailed electrical specifications, thermal performance information, and application recommendations, refer to the datasheet provided by Rohm Semiconductor. This MOSFET is a reliable and efficient choice for various small signal switching applications in modern electronic devices.