Radiated Power Measurement: Difference between revisions
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(New page: Related wiki page: Feedlines, Capacity Hats, Antenna Design, Gain, Bands, SWR, harmonics, Front-to-back ratio Electromagnetic Waves ==Power Ratio dBm o...) |
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Related wiki page: [[Feedlines]], [[Capacity Hats]], [[Antenna Design]], [[Gain]], [[Bands]], [[SWR]], [[harmonics]], [[Front-to-back ratio]] [[Electromagnetic Waves]] | Related wiki page: [[Feedlines]], [[Capacity Hats]], [[Decibels]], [[Antenna Design]], [[Gain]], [[Bands]], [[SWR]], [[harmonics]], [[Front-to-back ratio]] [[Electromagnetic Waves]] | ||
==Power Ratio dBm or dBmW == | ==Power Ratio dBm or dBmW == | ||
The power compared to a 1 milliwatt (1mW) source, expressed in decibels (dB) | The power compared to a 1 milliwatt (1mW) source, expressed in decibels ([[Decibels| dB]]) | ||
Formula: | Formula: | ||
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more information can be found [http://en.wikipedia.org/wiki/DBm here] | more information can be found [http://en.wikipedia.org/wiki/DBm here] | ||
{{electronics}} | |||
Latest revision as of 17:18, 8 April 2009
Related wiki page: Feedlines, Capacity Hats, Decibels, Antenna Design, Gain, Bands, SWR, harmonics, Front-to-back ratio Electromagnetic Waves
Power Ratio dBm or dBmW
The power compared to a 1 milliwatt (1mW) source, expressed in decibels ( dB)
Formula:
<math> x = 10 \log_{10}(P/1 \ \mathrm{mW}) \, </math>
Where P is the power in watts (W)
This roughly equates to:
- Double the power = 3dB increase in dBm
- Halve the power = 3dB decrease in dBm
| dBm level | Power |
|---|---|
| 80 dBm | 100 kW |
| 60 dBm | 1 kW = 1000 W |
| 50 dBm | 100 W |
| 40 dBm | 10 W |
| 36 dBm | 4 W |
| 33 dBm | 2 W |
| 30 dBm | 1 W = 1000 mW |
| 27 dBm | 500 mW |
| 26 dBm | 400 mW |
| 25 dBm | 316 mW |
| 24 dBm | 250 mW |
| 23 dBm | 200 mW |
| 22 dBm | 160 mW |
| 21 dBm | 125 mW |
| 20 dBm | 100 mW |
| 15 dBm | 32 mW |
| 10 dBm | 10 mW |
| 6 dBm | 4.0 mW |
| 5 dBm | 3.2 mW |
| 4 dBm | 2.5 mW |
| 3 dBm | 2.0 mW |
| 2 dBm | 1.6 mW |
| 1 dBm | 1.3 mW |
| 0 dBm | 1.0 mW = 1000 µW |
| −1 dBm | 794 µW |
| −3 dBm | 501 µW |
| −5 dBm | 316 µW |
| −10 dBm | 100 µW |
| −20 dBm | 10 µW |
| −30 dBm | 1.0 µW = 1000 nW |
| −40 dBm | 100 nW |
| −50 dBm | 10 nW |
| −60 dBm | 1.0 nW = 1000 pW |
| −70 dBm | 100 pW |
| −80 dBm | 10 pW |
| −100 dBm | 0.1 pW |
| −111 dBm | 0.008 pW = 8 fW |
| −127.5 dBm | 0.178 fW = 178 aW |
| −174 dBm | 0.004 aW |
| −192.5 dBm | 0.00004 aW |
| −∞ dBm | 0 W |
more information can be found here
| Electronic Theory | |
| Physical quantities | Current * Gain * Impedance * Power * Q of a circuit * Radiated Power Measurement * Reactance* Resistivity * Resonance * Voltage |
| Components | Baluns * Bipolar-Junction Transistors * Capacitors * Diodes * Inductors* Lasers * Microphones * Resistors * Transformers * Wire |
| Circuits | Attenuators * Digital Signal Processing (DSP) * Dummy load * Filters * LC filters * Power Supply Design * Rectifier Circuits |
| Design | Amplifier Design * Oscillator Design |
| Electromagnetic Waves | Relative power (Decibels) * Harmonics * Interference and BPL |