Invertor Electric Effort 2 Calculator

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✖Delay of Chains refers to the propagation delay of a series of logic gates connected in a chain.ⓘ Delay of Chains [D_C]			+10% -10%
✖The Electric Effort 1 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 [h₁]			+10% -10%
✖Inverter Power is the power delivered by invertor.ⓘ Inverter Power [P_inv]			+10% -10%

✖The Electric Effort 2 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.ⓘ Invertor Electric Effort 2 [h₂]

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Invertor Electric Effort 2

Formula

`"h"_{"2"} = "D"_{"C"}-("h"_{"1"}+2*"P"_{"inv"})`

Example

`"31mW"="0.05s"-("2.14mW"+2*"8.43mW")`

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Invertor Electric Effort 2 Solution

STEP 0: Pre-Calculation Summary

Formula Used

Electric Effort 2 = Delay of Chains-(Electric Effort 1+2*Inverter Power)
h₂ = D_C-(h₁+2*P_inv)
This formula uses 4 Variables

Variables Used

Electric Effort 2 - (Measured in Watt) - The Electric Effort 2 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.
Delay of Chains - (Measured in Second) - Delay of Chains refers to the propagation delay of a series of logic gates connected in a chain.
Electric Effort 1 - (Measured in Watt) - The Electric Effort 1 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.
Inverter Power - (Measured in Watt) - Inverter Power is the power delivered by invertor.

STEP 1: Convert Input(s) to Base Unit

Delay of Chains: 0.05 Second --> 0.05 Second No Conversion Required
Electric Effort 1: 2.14 Milliwatt --> 0.00214 Watt (Check conversion here)
Inverter Power: 8.43 Milliwatt --> 0.00843 Watt (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

h₂ = D_C-(h₁+2*P_inv) --> 0.05-(0.00214+2*0.00843)

Evaluating ... ...

h₂ = 0.031

STEP 3: Convert Result to Output's Unit

0.031 Watt -->31 Milliwatt (Check conversion here)

FINAL ANSWER

31 Milliwatt <-- Electric Effort 2

(Calculation completed in 00.004 seconds)

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Invertor Electric Effort 2 Formula

Electric Effort 2 = Delay of Chains-(Electric Effort 1+2*Inverter Power)
h₂ = D_C-(h₁+2*P_inv)

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How to Calculate Invertor Electric Effort 2?

Invertor Electric Effort 2 calculator uses Electric Effort 2 = Delay of Chains-(Electric Effort 1+2*Inverter Power) to calculate the Electric Effort 2, The Invertor Electric Effort 2 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 2 is denoted by h₂ symbol.

How to calculate Invertor Electric Effort 2 using this online calculator? To use this online calculator for Invertor Electric Effort 2, enter Delay of Chains (D_C), Electric Effort 1 (h₁) & Inverter Power (P_inv) and hit the calculate button. Here is how the Invertor Electric Effort 2 calculation can be explained with given input values -> 31620 = 0.05-(0.00214+2*0.00843).

FAQ

What is Invertor Electric Effort 2?

The Invertor Electric Effort 2 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 h₂ = D_C-(h₁+2*P_inv) or Electric Effort 2 = Delay of Chains-(Electric Effort 1+2*Inverter Power). Delay of Chains refers to the propagation delay of a series of logic gates connected in a chain, The Electric Effort 1 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 & Inverter Power is the power delivered by invertor.

How to calculate Invertor Electric Effort 2?

The Invertor Electric Effort 2 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 2 = Delay of Chains-(Electric Effort 1+2*Inverter Power). To calculate Invertor Electric Effort 2, you need Delay of Chains (D_C), Electric Effort 1 (h₁) & Inverter Power (P_inv). With our tool, you need to enter the respective value for Delay of Chains, Electric Effort 1 & Inverter Power and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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