Power Per Unit Bandwidth Solution

STEP 0: Pre-Calculation Summary
Formula Used
Power per Unit = Thermal Resistance*Resistor Absolute Temperature
Pu = k*TR
This formula uses 3 Variables
Variables Used
Power per Unit - (Measured in Watt) - Power per unit provides units for power and is denoted by P symbol.
Thermal Resistance - (Measured in Kelvin per Watt) - Thermal resistance is a property of the resistor that quantifies how effectively it dissipates heat. It is measured in Kelvin per watt (k/w).
Resistor Absolute Temperature - (Measured in Kelvin) - Resistor Absolute Temperature refers to the change in electrical resistance of a resistor with respect to temperature. It quantifies how resistance varies as the temperature changes.
STEP 1: Convert Input(s) to Base Unit
Thermal Resistance: 12.25 Kelvin per Watt --> 12.25 Kelvin per Watt No Conversion Required
Resistor Absolute Temperature: 12.245 Kelvin --> 12.245 Kelvin No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Pu = k*TR --> 12.25*12.245
Evaluating ... ...
Pu = 150.00125
STEP 3: Convert Result to Output's Unit
150.00125 Watt --> No Conversion Required
FINAL ANSWER
150.00125 150.0012 Watt <-- Power per Unit
(Calculation completed in 00.004 seconds)

Credits

Created by Shobhit Dimri
Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat
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Birsa Institute of Technology (BIT), Sindri
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24 Antenna Theory Parameters Calculators

Distance between Transmitting and Receiving Point
Go Transmitter Receiver Distance = (Antenna Current*120*pi*Height of Transmitter*Height of Receiver)/(Strength of Ground Wave Propagation*Wavelength)
Height of Transmitting Antenna
Go Height of Transmitter = (Strength of Ground Wave Propagation*Wavelength*Transmitter Receiver Distance)/(120*pi*Antenna Current*Height of Receiver)
Height of Receiving Antenna
Go Height of Receiver = (Strength of Ground Wave Propagation*Wavelength*Transmitter Receiver Distance)/(120*pi*Height of Transmitter*Antenna Current)
Antenna Current
Go Antenna Current = (Strength of Ground Wave Propagation*Wavelength*Transmitter Receiver Distance)/(120*pi*Height of Transmitter*Height of Receiver)
Strength of Ground Wave
Go Strength of Ground Wave Propagation = (120*pi*Height of Transmitter*Height of Receiver*Antenna Current)/(Wavelength*Transmitter Receiver Distance)
Friis Formula
Go Power at Receiving Antenna = Transmitting Power*Gain of Receiving Antenna*Gain of Transmitting Antenna*Wavelength^2/(4*3.14*Transmitter Receiver Distance)^2
Power Density of Antenna
Go Power Density of Antenna = (Total Input Power*Antenna Gain)/(4*pi*Transmitter Receiver Distance)
Effective Area of Antenna
Go Effective Area Antenna = (Thermal Resistance*Incremental Temperature)/Power Density of Antenna
Noise Temperature of Antenna
Go Antenna Temperature = (Power Density of Antenna)/(Thermal Resistance*Bandwidth)
Total Power of Antenna
Go Total Power of Antenna = Thermal Resistance*Antenna Temperature*Bandwidth
Radiation Intensity
Go Radiation Intensity = Isotropic Radiation Intensity*Directivity of Antenna
Average Radiation Intensity
Go Average Radiation Intensity = Radiation Intensity/Directivity of Antenna
Directivity of Antenna
Go Directivity of Antenna = Radiation Intensity/Average Radiation Intensity
Radiation Resistance
Go Radiation Resistance = Total Antenna Resistance-Ohmic Resistance
Ohmic Resistance
Go Ohmic Resistance = Total Antenna Resistance-Radiation Resistance
Power Per Unit Bandwidth
Go Power per Unit = Thermal Resistance*Resistor Absolute Temperature
Total Antenna Resistance
Go Total Antenna Resistance = Ohmic Resistance+Radiation Resistance
Antenna Gain
Go Antenna Gain = Radiation Intensity/Isotropic Radiation Intensity
Length of Binomial Array
Go Length of Binomial Array = (No of Element-1)*Wavelength/2
Isotropic Radiation Intensity
Go Isotropic Radiation Intensity = Radiated Power/(4*pi)
Total Input Power
Go Total Input Power = Radiated Power/Antenna Efficiency
Antenna Efficiency
Go Antenna Efficiency = Radiated Power/Total Input Power
Duct Height
Go Duct Height = (Maximum Duct Wavelength/0.014)^(2/3)
Maximum Duct Wavelength
Go Maximum Duct Wavelength = 0.014*Duct Height^(3/2)

Power Per Unit Bandwidth Formula

Power per Unit = Thermal Resistance*Resistor Absolute Temperature
Pu = k*TR

What is Antenna Temperature?

Antenna Temperature is a measure of the noise being produced by an antenna in a given environment. This is also called an Antenna Noise Temperature. It is not the physical temperature of the antenna.

How to Calculate Power Per Unit Bandwidth?

Power Per Unit Bandwidth calculator uses Power per Unit = Thermal Resistance*Resistor Absolute Temperature to calculate the Power per Unit, The Power Per Unit Bandwidth formula is defined as provides units for power, voltage, current, impedance, and admittance. With the exception of impedance and admittance, any two units are independent and can be selected as base values; power and voltage are typically chosen. Power per Unit is denoted by Pu symbol.

How to calculate Power Per Unit Bandwidth using this online calculator? To use this online calculator for Power Per Unit Bandwidth, enter Thermal Resistance (k) & Resistor Absolute Temperature (TR) and hit the calculate button. Here is how the Power Per Unit Bandwidth calculation can be explained with given input values -> 150.0012 = 12.25*12.245.

FAQ

What is Power Per Unit Bandwidth?
The Power Per Unit Bandwidth formula is defined as provides units for power, voltage, current, impedance, and admittance. With the exception of impedance and admittance, any two units are independent and can be selected as base values; power and voltage are typically chosen and is represented as Pu = k*TR or Power per Unit = Thermal Resistance*Resistor Absolute Temperature. Thermal resistance is a property of the resistor that quantifies how effectively it dissipates heat. It is measured in Kelvin per watt (k/w) & Resistor Absolute Temperature refers to the change in electrical resistance of a resistor with respect to temperature. It quantifies how resistance varies as the temperature changes.
How to calculate Power Per Unit Bandwidth?
The Power Per Unit Bandwidth formula is defined as provides units for power, voltage, current, impedance, and admittance. With the exception of impedance and admittance, any two units are independent and can be selected as base values; power and voltage are typically chosen is calculated using Power per Unit = Thermal Resistance*Resistor Absolute Temperature. To calculate Power Per Unit Bandwidth, you need Thermal Resistance (k) & Resistor Absolute Temperature (TR). With our tool, you need to enter the respective value for Thermal Resistance & Resistor Absolute Temperature 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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