Attenuators: Difference between revisions

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* To produce low power for [[QRP | QRP]] transmissions. many modern HF rigs have a minimum power out of around 5 Watts. QRP operators usually use powers well below this.
* To produce low power for [[QRP | QRP]] transmissions. many modern HF rigs have a minimum power out of around 5 Watts. QRP operators usually use powers well below this.


=Attenuator Circuits =
==Attenuator Circuits ==


==The pi circuit==
===The pi circuit===


In the circuit below, known as a pi pad;
In the circuit below, known as a pi pad;
Line 25: Line 25:
Approximate resistor values for a single pi pad are as follows
Approximate resistor values for a single pi pad are as follows


{| style = width:55 border ="1"
[[Image:Pi_pad.jpg | 300px]]
|Attenuation dB || Arm resistor  || Leg resistors
 
|----
|3dB ||17.6 || 292.4
|----
|6dB || 37.4 || 150.5
|----
|10dB || 71.2 || 96.2
|----
|20dB || 247.5 || 61.1
|----
|----|}


== The T circuit ==
=== The T circuit ===


In the circuit below, known as a T pad;
In the circuit below, known as a T pad;
Line 48: Line 38:
[[Image:T-pad.jpg |250px]]
[[Image:T-pad.jpg |250px]]


Approximate resistor values for a single T pad are as follows
[[Image:t_pad.jpg | 300px]]
=== The H circuit ===
Also known as the H pad or I circuit(I pad)
=== The O circuit===
Also known as the O pad.
==Online attenuator calculators==
* [http://www.nu9n.com/tpad-calculator.html T and H pad calculators]from NU9N
* [http://www.softpedia.com/progClean/Attenuator-Calculator-Clean-119756.html Attenuator calculator 1.2] Attenuator calculator software.


* [http://chemandy.com/calculators/pi_attenuator_calculator.htm Pi calculator]


= How is attenuation measured?=
* [http://www.daycounter.com/Calculators/PI-T-Pad-Attenuator-Calculator.phtml Pi and T pad calculator]
 
 
== How is attenuation measured?==


Attenuation is measured in decibels (dB) of relative power. A guide to the attenuation-dB relationship is:
Attenuation is measured in decibels (dB) of relative power. A guide to the attenuation-dB relationship is:
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|----
|----
|----|}
|----|}
{{electronics}}

Latest revision as of 20:39, 27 July 2009

Related wiki pages; Apparatus, Dummy Load

What is an attenuator?

An attenuator is a resistive device that reduces the amplitude of a signal without adding distortion to it. The amplitude of a radio signal is the power, so an attenuator is used to reduce the power of a transmission.

When would we use one?

  • When making transmission measurements using highly sensitive equipment. The attenuator reduces power to protect the measuring equipment.
  • To produce low power for QRP transmissions. many modern HF rigs have a minimum power out of around 5 Watts. QRP operators usually use powers well below this.

Attenuator Circuits

The pi circuit

In the circuit below, known as a pi pad;

  • RA = Arm resistor
  • <math>RL_1</math> = leg resistor 1
  • <math>RL_2</math> = leg resistor 2

PI-attenuator.png

Approximate resistor values for a single pi pad are as follows

Pi pad.jpg


The T circuit

In the circuit below, known as a T pad;

  • RL = Leg resistor
  • <math>RA_1</math> = Arm resistor 1
  • <math>RA_2</math> = Arm resistor 2

T-pad.jpg

Approximate resistor values for a single T pad are as follows

T pad.jpg

The H circuit

Also known as the H pad or I circuit(I pad)

The O circuit

Also known as the O pad.

Online attenuator calculators


How is attenuation measured?

Attenuation is measured in decibels (dB) of relative power. A guide to the attenuation-dB relationship is:

dB Attenuation Power in Power out
3dB 0.5 100W 50W
6dB 0.25 100W 25W
10dB 0.1 100W 10W
20dB 0.01 100W 1W
30dB 0.001 100W 0.1W
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