The part number "NC7SZ04M5X" corresponds to a component produced by ON Semiconductor. This specific part is a Hex Inverter with Schmitt Trigger inputs. It is designed to be used in logic applications, where signal conditioning and high noise immunity are essential.
Package and Pinout
The NC7SZ04M5X comes in a SOT-23-5 package, which is a 5-pin package. The pinout is designed to support high-speed logic in a small form factor.
Pin Function List (5 Pins)
Here is a detailed explanation of the pin functions for the NC7SZ04M5X, which has 5 pins in total:
Pin Number Pin Name Pin Function Pin 1 A Input Pin: The Schmitt Trigger input where the signal is applied to drive the inverter logic. Pin 2 Y Output Pin: The output of the inverter, which provides the inverted logic signal from the input. Pin 3 NC No Connect (this pin is not connected internally and is typically left floating or unconnected). Pin 4 Vcc Power Supply Pin: The positive supply voltage for the logic device (typically 5V or 3.3V). Pin 5 GND Ground Pin: The reference ground for the device, necessary to complete the electrical circuit.Pinout Diagram (SOT-23-5 Package)
For a visual representation of how these pins are laid out in the SOT-23-5 package, the diagram can be described as follows:
+---------+ | 1 | 2 | | A | Y | +---------+ | 5 | 4 | | GND| Vcc| +---------+Where:
Pin 1 (A) is the input. Pin 2 (Y) is the output. Pin 4 (Vcc) is the power supply. Pin 5 (GND) is the ground.Circuit Principle and Function
The NC7SZ04M5X is a Schmitt Trigger Hex Inverter. This means that the device has built-in hysteresis that allows for clean transitions in noisy environments. It provides a more stable output in situations where the input signal might be noisy or undefined, thus ensuring reliable logic operation.
Each gate in the device inverts its input signal, so if the input (Pin A) is high, the output (Pin Y) will be low, and vice versa.
The device is commonly used in:
Signal processing where clean signal transitions are critical. Noise-sensitive environments, such as automotive electronics, industrial control, and communication systems.FAQs (Frequently Asked Questions)
Q: What is the supply voltage range for NC7SZ04M5X? A: The supply voltage range for the NC7SZ04M5X is typically 2.0V to 5.5V. Q: What is the logic family of NC7SZ04M5X? A: The logic family of the NC7SZ04M5X is part of ON Semiconductor's "S-Z" family of advanced CMOS logic gates. Q: What is the purpose of the Schmitt Trigger input? A: The Schmitt Trigger input provides hysteresis to ensure reliable and clean transitions in noisy environments. Q: Can the NC7SZ04M5X be used in low-voltage applications? A: Yes, the NC7SZ04M5X is designed to operate in low-voltage environments, making it suitable for both 3.3V and 5V systems. Q: What is the current consumption of NC7SZ04M5X? A: The current consumption of the NC7SZ04M5X is typically very low, usually in the range of nanoamperes for input signals at logic levels. Q: Is NC7SZ04M5X suitable for use in high-speed digital circuits? A: Yes, it is designed for high-speed operation with fast switching speeds, making it suitable for many high-speed digital logic applications. Q: What is the maximum input voltage for the NC7SZ04M5X? A: The maximum input voltage for the NC7SZ04M5X is typically equal to the supply voltage (Vcc) plus 0.5V. Q: Can the NC7SZ04M5X be used in 3.3V logic systems? A: Yes, the NC7SZ04M5X is fully compatible with 3.3V logic systems. Q: How does the Schmitt Trigger affect signal integrity? A: The Schmitt Trigger improves signal integrity by reducing the effect of noise and providing clean transitions between logic levels.Q: What happens if the input (Pin A) is floating?
A: If the input is floating, the output (Pin Y) may become unpredictable or undefined.Q: Can NC7SZ04M5X be used for both logic high and low-level signals?
A: Yes, the device can handle both high and low-level signals, but the Schmitt Trigger ensures that input noise does not cause errors.Q: Does the NC7SZ04M5X require any external components for stability?
A: Typically, no external components are needed, as the device is designed to be self-contained for most standard logic applications.Q: What is the maximum output current for NC7SZ04M5X?
A: The maximum output current for the NC7SZ04M5X is typically around 4mA.Q: What is the propagation delay for NC7SZ04M5X?
A: The propagation delay is typically very fast, usually in the range of 2-4ns, depending on the supply voltage and other factors.Q: What is the input threshold voltage for NC7SZ04M5X?
A: The input threshold voltage varies depending on the supply voltage but is typically around 1/3 of Vcc for low-level input and 2/3 of Vcc for high-level input.Q: Can I use the NC7SZ04M5X in temperature-sensitive applications?
A: Yes, it has a wide operating temperature range and can function reliably in various environmental conditions, including automotive applications.Q: Does NC7SZ04M5X support open-drain outputs?
A: No, the NC7SZ04M5X does not support open-drain outputs; it provides standard CMOS output.Q: What is the capacitance on the inputs for the NC7SZ04M5X?
A: The input capacitance is typically low, around 2pF, making it suitable for high-speed applications.Q: Can I connect multiple NC7SZ04M5X devices together?
A: Yes, multiple devices can be connected in series or parallel in digital logic circuits, as long as proper voltage and current requirements are met.Q: What is the typical application of the NC7SZ04M5X?
A: Typical applications include signal conditioning, digital logic circuits, noise filtering, and high-speed switching.I hope this information helps! If you have further questions or need more detailed explanations, feel free to ask.
