CMF5511K500FHEA

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Through Hole Resistors

Through hole resistors, typically called THRs, are a type of electric component used to create electrical paths with specific fixed resistance values. These components are mainly used to support the current flow and voltage through devices such as electrical circuits and for regulating current and voltage in a circuit. THRs offer a range of benefits, such as improved thermal stability, increased performance, and a robust structure that can be used in a range of electrical applications.

The CMF5511K500FHEA is a type of through hole resistor. It is a high precision, low-impedance, glass-encapsulated Axial-lead resistors with both edges of the resistor element flattened against the end cap. The device has a resistance value of 500 Ohm, and is molded in an epoxy body with a glass-flattened section. It is designed with a high thermal stability, and offers a high Q-point accuracy of ±1%. In addition, the device has a flat profile, a symmetrical design, and requires minimal force for lead insertion and removal.

Application field

The CMF5511K500FHEA is suitable for various types of electronic circuits. It has wide application fields including power suppression, measurement and control, power management, analog-to-digital conversion, etc. It is also used in motor control, power supplies, measurement and control instruments, as well as in mobile and other portable device applications.

The CMF5511K500FHEA is ideal for high-precision applications that require high resistance and high Q-point accuracy, such as in the automotive, medical, industrial and consumer markets. The device also works well in audio and video equipment, satellite communication systems, stabilizers, and power amplifiers.

Working principle

The working principle of the CMF5511K500FHEA is similar to that of other resistors. It consists of a metallic element that is connected between two terminals, and which generates electrical resistance. When a current is applied to the device, it creates a voltage drop across the terminals, and this voltage drop is proportional to the applied current.

The voltage drop across the resistor is determined by the magnitude of the applied current and the resistance value of the resistor. The voltage drop is equal to the value of the applied current multiplied by the resistance of the device – in this case, the resistance of the CMF5511K500FHEA is 500 Ohms. The working principle of the CMF5511K500FHEA can be explained using Ohm’s Law, which states that the voltage drop (V) is equal to the current (I) multiplied by the resistance (R).

In addition, the working principle of the CMF5511K500FHEA can be explained by Faraday\'s Law, which states that the electromotive force (EMF) is equal to the rate of change of the magnetic flux. This means that when the current through the device is changing with time, there will be a corresponding EMF produced across the resistor. The magnitude of the EMF is determined by the magnitude of the current and resistance of the device.

The CMF5511K500FHEA is a high-precision device offering a range of advantages in terms of performance, thermal stability, and reduced assembly and maintenance costs. Its resistance value of 500 Ohm is suitable for many types of electronic circuits, and its symmetrical design ensures that lead insertion and removal require minimal force. It is also suitable for use in a variety of power applications due to its ability to provide accurate Q-point accuracy.

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