Static Power Dissipation Calculator

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✖Static Current is an imbalance of electric charges within or on the surface of a material.ⓘ Static Current [i_static]			+10% -10%
✖Base Collector Voltage is a crucial parameter in transistor biasing. It refers to the voltage difference between the base and collector terminals of the transistor when it is in its active state.ⓘ Base Collector Voltage [V_bc]			+10% -10%

✖Static power is primarily leakage power and is caused by the transistor not completely turning off.ⓘ Static Power Dissipation [P_static]

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Formula

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Static Power Dissipation

Formula

`"P"_{"static"} = "i"_{"static"}*"V"_{"bc"}`

Example

`"5.9994mW"="2.97mA"*"2.02V"`

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Static Power Dissipation Solution

STEP 0: Pre-Calculation Summary

Formula Used

Static Power = Static Current*Base Collector Voltage
P_static = i_static*V_bc
This formula uses 3 Variables

Variables Used

Static Power - (Measured in Watt) - Static power is primarily leakage power and is caused by the transistor not completely turning off.
Static Current - (Measured in Ampere) - Static Current is an imbalance of electric charges within or on the surface of a material.
Base Collector Voltage - (Measured in Volt) - Base Collector Voltage is a crucial parameter in transistor biasing. It refers to the voltage difference between the base and collector terminals of the transistor when it is in its active state.

STEP 1: Convert Input(s) to Base Unit

Static Current: 2.97 Milliampere --> 0.00297 Ampere (Check conversion here)
Base Collector Voltage: 2.02 Volt --> 2.02 Volt No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

P_static = i_static*V_bc --> 0.00297*2.02

Evaluating ... ...

P_static = 0.0059994

STEP 3: Convert Result to Output's Unit

0.0059994 Watt -->5.9994 Milliwatt (Check conversion here)

FINAL ANSWER

5.9994 Milliwatt <-- Static Power

(Calculation completed in 00.004 seconds)

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< 24 CMOS Design Characteristics Calculators

Ground to Agression Capacitance

Go Adjacent Capacitance = ((Victim Driver*Time Constant Ratio*Ground Capacitance)-(Agression Driver*Ground A Capacitance))/(Agression Driver-Victim Driver*Time Constant Ratio)

Victim Driver

Go Victim Driver = (Agression Driver*(Ground A Capacitance+Adjacent Capacitance))/(Time Constant Ratio*(Adjacent Capacitance+Ground Capacitance))

Agression Driver

Go Agression Driver = (Victim Driver*Time Constant Ratio*(Adjacent Capacitance+Ground Capacitance))/(Ground A Capacitance+Adjacent Capacitance)

Thermal Voltage of CMOS

Go Thermal Voltage = Built-in Potential/ln((Acceptor Concentration*Donor Concentration)/(Intrinsic Electron Concentration^2))

Built-in Potential

Go Built-in Potential = Thermal Voltage*ln((Acceptor Concentration*Donor Concentration)/(Intrinsic Electron Concentration^2))

Agressor Voltage

Go Agressor Voltage = (Victim Voltage*(Ground Capacitance+Adjacent Capacitance))/Adjacent Capacitance

Victim Voltage

Go Victim Voltage = (Agressor Voltage*Adjacent Capacitance)/(Ground Capacitance+Adjacent Capacitance)

Adjacent Capacitance

Go Adjacent Capacitance = (Victim Voltage*Ground Capacitance)/(Agressor Voltage-Victim Voltage)

Branching Effort

Go Branching Effort = (Capacitance Onpath+Capacitance Offpath)/Capacitance Onpath

Output Clock Phase

Go Output Clock Phase = 2*pi*VCO Control Voltage*VCO Gain

Total Capacitance Seen by Stage

Go Total Capacitance in Stage = Capacitance Onpath+Capacitance Offpath

Capacitance Offpath

Go Capacitance Offpath = Total Capacitance in Stage-Capacitance Onpath

Capacitance Onpath

Go Capacitance Onpath = Total Capacitance in Stage-Capacitance Offpath

Time Constant Ratio of Agression to Victim

Go Time Constant Ratio = Agression Time Constant/Victim Time Constant

Agression Time Constant

Go Agression Time Constant = Time Constant Ratio*Victim Time Constant

Victim Time Constant

Go Victim Time Constant = Agression Time Constant/Time Constant Ratio

Off-Path Capacitance of CMOS

Go Capacitance Offpath = Capacitance Onpath*(Branching Effort-1)

Change in Frequency Clock

Go Change in Frequency of Clock = VCO Gain*VCO Control Voltage

VCO Single Gain Factor

Go VCO Gain = Change in Frequency of Clock/VCO Control Voltage

VCO Control Voltage

Go VCO Control Voltage = Lock Voltage+VCO Offset Voltage

VCO Offset Voltage

Go VCO Offset Voltage = VCO Control Voltage-Lock Voltage

Lock Voltage

Go Lock Voltage = VCO Control Voltage-VCO Offset Voltage

Static Power Dissipation

Go Static Power = Static Current*Base Collector Voltage

Static Current

Go Static Current = Static Power/Base Collector Voltage

Static Power Dissipation Formula

Static Power = Static Current*Base Collector Voltage
P_static = i_static*V_bc

What is dynamic and static power?

Energy is required to charge and discharge the load capacitance. This is called dynamic power because it is consumed when the circuit is actively switching. Even when the gate is not switching, it draws some static power. Because an OFF transistor is leaky, a small amount of current Istatic flows between power and ground, resulting in a static power dissipation.

How to Calculate Static Power Dissipation?

Static Power Dissipation calculator uses Static Power = Static Current*Base Collector Voltage to calculate the Static Power, The Static Power Dissipation formula is defined static electricity is an imbalance of electric charges within or on the surface of a material. Static Power is denoted by P_static symbol.

How to calculate Static Power Dissipation using this online calculator? To use this online calculator for Static Power Dissipation, enter Static Current (i_static) & Base Collector Voltage (V_bc) and hit the calculate button. Here is how the Static Power Dissipation calculation can be explained with given input values -> 5900.796 = 0.00297*2.02.

FAQ

What is Static Power Dissipation?

The Static Power Dissipation formula is defined static electricity is an imbalance of electric charges within or on the surface of a material and is represented as P_static = i_static*V_bc or Static Power = Static Current*Base Collector Voltage. Static Current is an imbalance of electric charges within or on the surface of a material & Base Collector Voltage is a crucial parameter in transistor biasing. It refers to the voltage difference between the base and collector terminals of the transistor when it is in its active state.

How to calculate Static Power Dissipation?

The Static Power Dissipation formula is defined static electricity is an imbalance of electric charges within or on the surface of a material is calculated using Static Power = Static Current*Base Collector Voltage. To calculate Static Power Dissipation, you need Static Current (i_static) & Base Collector Voltage (V_bc). With our tool, you need to enter the respective value for Static Current & Base Collector Voltage 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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