Well if the FET had very high resistance, then I guess there wouldn't be any drop across it. Leakage current would be zero as it's like an open circuit. So voltage would be 5 VNascentOxygen said:
Uhmm, would you like to re-think that statement?jaus tail said:
If the FET has very high resistance (both FET in series), the resistance of the path becomes very high and resistance will oppose any current. Unless the current is being forced to flow through it. In that case the voltage would be very high.Tom.G said:
Doesn't Vss do that?jaus tail said:
The circuit given is a simplification of the output stage of a CMOS logic device. The 0-state reference would be to indicate that the output voltage should be a logic LOW level. The reference to Ileakage points out that devices in their Off state have a high but finite resistance, allowing a little bit of current to flow. The example circuit given has exaggerated the resistance of the supposedly Off FET to be a lower value than is commonly found.jaus tail said:
The voltage divider rule for CMOS in 0-state is used to determine the voltage distribution between two resistors in series. This is important in CMOS circuits as it helps to maintain a stable voltage level and ensure proper functioning of the circuit.
The voltage divider rule helps to reduce leakage current in CMOS circuits by ensuring that the voltage across each resistor is equal. This means that the leakage current will also be evenly distributed, reducing its overall impact on the circuit.
The accuracy of the voltage divider rule in CMOS circuits can be affected by factors such as temperature, variations in resistor values, and supply voltage fluctuations. These factors can cause deviations from the expected voltage distribution and may need to be taken into account for more precise calculations.
Yes, the voltage divider rule can be applied to non-CMOS circuits as well. It is a general rule that can be used to determine the voltage distribution in any circuit with two resistors in series. However, the specific values of the resistors and other circuit parameters may vary.
The voltage divider rule is commonly used in CMOS circuits for biasing, level shifting, and voltage regulation. It is also used in the design of analog-to-digital converters, amplifiers, and other electronic devices. Additionally, it can be used to calculate the voltage at different nodes in a circuit, aiding in circuit analysis and troubleshooting.