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Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat
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Invertor Electric Effort 1 Solution

STEP 0: Pre-Calculation Summary
Formula Used
electric_effort_1 = Delay of Chains-(electric effort 2+2*invertor power)
h1 = D-(h2+2*Pinv)
This formula uses 3 Variables
Variables Used
Delay of Chains- Delay of Chains is the total of two inverters is matched against the delay of three when driving a fanout of F.
electric effort 2- electric effort 2 is the second invertor electric effort
invertor power- invertor power is the power delivered by invertor
STEP 1: Convert Input(s) to Base Unit
Delay of Chains: 10 --> No Conversion Required
electric effort 2: 5 --> No Conversion Required
invertor power: 8 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
h1 = D-(h2+2*Pinv) --> 10-(5+2*8)
Evaluating ... ...
h1 = -11
STEP 3: Convert Result to Output's Unit
-11 --> No Conversion Required
FINAL ANSWER
-11 <-- electric effort 1
(Calculation completed in 00.000 seconds)

10+ CMOS-VLSI Design Calculators

Drain Voltage
drain_voltage = sqrt(dynamic power/frequency*Capacitance) Go
Gate to Channel Voltage
gate_to_channel_voltage = (Channel Charge/Gate Capacitance)+Threshold voltage Go
Threshold Voltage
threshold_voltage = Gate to Channel Voltage-(Channel Charge/Gate Capacitance) Go
Gate Capacitance
channel_charge = Gate Capacitance*(Gate to Channel Voltage-Threshold voltage) Go
Channel Charge
channel_charge = Gate Capacitance*(Gate to Channel Voltage-Threshold voltage) Go
Capacitor dynamic power
dynamic_power = Drain Voltage^2*frequency*Capacitance Go
Potential gate to Collector
potential_gate_to_collector = (Potential Gate to Source+Potential Gate to Drain)/2 Go
Potential Gate to Drain
potential_gate_to_drain = 2*potential gate to collector-Potential Gate to Source Go
Static Current
static_current = Static power/Drain Voltage Go
Static Power Dissipation
static_power = static current*Drain Voltage Go

Invertor Electric Effort 1 Formula

electric_effort_1 = Delay of Chains-(electric effort 2+2*invertor power)
h1 = D-(h2+2*Pinv)

What are Clock Chopper?

They can produce a variety of modified clock waveforms including pulsed clocks, delayed clocks, stretched clocks, nonoverlapping clocks, and double-frequency pulsed clocks. When used to modify the clock edges, they are sometimes called clock choppers or clock stretchers.

How to Calculate Invertor Electric Effort 1?

Invertor Electric Effort 1 calculator uses electric_effort_1 = Delay of Chains-(electric effort 2+2*invertor power) to calculate the electric effort 1, The Invertor Electric Effort 1 formula is defined as the electrical effort along a path through a network is simply the ratio of the capacitance that loads the last logic gate in the path to the input capacitance of the first gate in the path. . electric effort 1 and is denoted by h1 symbol.

How to calculate Invertor Electric Effort 1 using this online calculator? To use this online calculator for Invertor Electric Effort 1, enter Delay of Chains (D), electric effort 2 (h2) and invertor power (Pinv) and hit the calculate button. Here is how the Invertor Electric Effort 1 calculation can be explained with given input values -> -11 = 10-(5+2*8).

FAQ

What is Invertor Electric Effort 1?
The Invertor Electric Effort 1 formula is defined as the electrical effort along a path through a network is simply the ratio of the capacitance that loads the last logic gate in the path to the input capacitance of the first gate in the path. and is represented as h1 = D-(h2+2*Pinv) or electric_effort_1 = Delay of Chains-(electric effort 2+2*invertor power). Delay of Chains is the total of two inverters is matched against the delay of three when driving a fanout of F, electric effort 2 is the second invertor electric effort and invertor power is the power delivered by invertor.
How to calculate Invertor Electric Effort 1?
The Invertor Electric Effort 1 formula is defined as the electrical effort along a path through a network is simply the ratio of the capacitance that loads the last logic gate in the path to the input capacitance of the first gate in the path. is calculated using electric_effort_1 = Delay of Chains-(electric effort 2+2*invertor power). To calculate Invertor Electric Effort 1, you need Delay of Chains (D), electric effort 2 (h2) and invertor power (Pinv). With our tool, you need to enter the respective value for Delay of Chains, electric effort 2 and invertor power and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate electric effort 1?
In this formula, electric effort 1 uses Delay of Chains, electric effort 2 and invertor power. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • dynamic_power = Drain Voltage^2*frequency*Capacitance
  • drain_voltage = sqrt(dynamic power/frequency*Capacitance)
  • static_power = static current*Drain Voltage
  • static_current = Static power/Drain Voltage
  • channel_charge = Gate Capacitance*(Gate to Channel Voltage-Threshold voltage)
  • channel_charge = Gate Capacitance*(Gate to Channel Voltage-Threshold voltage)
  • gate_to_channel_voltage = (Channel Charge/Gate Capacitance)+Threshold voltage
  • threshold_voltage = Gate to Channel Voltage-(Channel Charge/Gate Capacitance)
  • potential_gate_to_collector = (Potential Gate to Source+Potential Gate to Drain)/2
  • potential_gate_to_drain = 2*potential gate to collector-Potential Gate to Source
Where is the Invertor Electric Effort 1 calculator used?
Among many, Invertor Electric Effort 1 calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
{FormulaExamplesList}
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