By Warren Paulson VE3FYN 28 February 2012 Version 1.0

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Presentation transcript:

By Warren Paulson VE3FYN 28 February 2012 Version 1.0 Exponents & Decibels By Warren Paulson VE3FYN 28 February 2012 Version 1.0

Magnitude We deal with both very large and very small numbers, often in the same circuit. A resistor may be 220,000 ohms. A capacitor may be 0.000000047 farads. A radio frequency may be 147,000,000 Hertz. We prefer numbers between 1 and 100. Which is easier to understand: “It’s 150 kilometres to Fort Frances,” or “It’s 150,000 metres to Fort Frances.”

Making Numbers Manageable To handle large numbers, we use multipliers. They are always multiples of 1000. 100,000 metres is better expressed in KILOmetres. A kilometre is 1000 metres long. So, 100,000 / 1000 = 100 kilometres . Likewise a millimetre is 1/1000 of a metre. So, 0.005 metres * 1000 = 5 mm (move the decimal).

Metric Units (really SI) Small numbers Large Numbers To change to larger units, divide. So, 2,200 ohms / 1000 = 2.2 kilo ohms, or 2.2 KΩ. To change to smaller units, multiply. So, 1.3 Gigahertz / * 1000 = 1,300 Megahertz, or 1,300 MHz. To change to smaller units, multiply. So, 0.345 amps x 1000 = 345 milliamps, or 345 mA. To change to larger units, divide. So, 4,700 picofarads / 1,000,000 = 0.0047 microfarads or 0.0047 uF. Name Value milli m 1/ 1,000 micro µ 1 / 1,000,000 nano n 1 / 1,000,000,000 pico p 1 / 1,000,000,000,000 Name Value Kilo K 1,000 Mega M 1,000,000 Giga G 1,000,000,000 Tera T 1,000,000,000,000 Note: Lowercase is used. Multiples of 1,000 are used. They are in alphabetical order. Note: Uppercase is used. Multiples of 1,000 are used. They are not multiples of 1024 unlike computers, which use base 2.

Exponents We can express any number multiplied by itself using exponents. 2 x 2 x 2 becomes 23. We read this as: “two to the power of three.” On most calculators, enter: “2 yx 3” or “2 yx 3”. Practice this on your own calculator, so you know how to do it for the test.

Base 10 Exponents Less than one Greater than one Number Exponent 0.1 10-1 0.01 10-2 0.001 10-3 0.0001 10-4 0.00001 10-5 We’re counting the decimal shift. Number Exponent 1 100 10 101 102 1000 103 10000 104 We’re really just counting the zeroes. Note: a negative exponent is just smaller than one; it doesn’t represent a negative number.

Scientific Notation (big numbers) Start with a big number: 147,120,000. Move the decimal point to the left until you get a number between one and ten, and keep count. 1 . 4 7 1 2 0 0 0 0 Write as 1.47 x 108, where ‘8’ is the number of positions you moved the decimal. On your calculator, it’s: “1.47 {Exp} 8”.

Exponential Change Change is often exponential. If you double the speed of your car, your braking distance quadruples. To get a noticeable increase in audio output, you need to double the signal strength. To get another noticeable increase, you need to double it again  what sounds like an incremental change is really a doubling of the sound level.

Audio Level Example 3 dB Change In this audio clip, white noise is decreasing in 3 dB increments. That is to say that each change represents half the previous power. 1 dB Change In this audio clip, white noise is decreasing in 1 dB increments. That is to say that each change represents about 3/4 the previous power. Source: http://www.animations.physics.unsw.edu.au/jw/dB.htm#soundfiles

Exponential Growth

Magnitudes of Change The first is a doubling from 2048 to 4096. The second is a doubling from 16,248 to 32,768. The 2048 unit increase in the first case is meaningless in the second. There are many cases, such as audio levels or receiver input levels, where each doubling represents the smallest meaningful magnitude of change. So, we need a numbering system where this is the same as this.

Magnitudes of Change (2) There’s another problem... The strongest signal your radio receives could be 2.5 billion times* stronger than the weakest. We need a numbering system that deals with this in a meaningful way. * Most S-meters go to 40 dB over S9. Each S-unit = 6 dB, so the total range is 54 dB + 40 dB, which is 94 dB.

The (dreaded) Decibel (1) Exponents manage these magnitudes of change. Consider 103 = 1,000. Increase that to 106, and we have 1,000,000. That’s 1000 times greater. This is the basis of the decibel. Our exponent has only increased by a manageable three units.

The Decibel (2) A decibel is not an absolute measure. It always represents a power ratio between two levels (usually a reference level). If your amplifier has 8 dB gain, its output is 8 dB stronger than its input. An antenna with 6 dB gain is 6 dB more sensitive (in the desired direction) than a reference antenna. An audio level of 3 dB is 3 dB stronger than a reference level of 20 micropascals. 3 – it can be expressed in terms of gain or loss. 4 – the math (1 and 2) 5 – how to add and subtract decibels 6 – the cheat

First, the Bel A Bel (developed by Bell Labs), is the power that 10 must be raised to, to give us our number. So, if we double our power output , the question is: 10? = 2. (Enter ‘2 log’ on your calculator). ‘Log’ calculates the base-10 exponent required to get our number. The answer is roughly 0.3. So doubling our power is 0.3 Bels.

Finally, the Decibel (1) Since decimals are a pain, the Decibel simply multiplies the Bel by 10. Its short-form is dB. If we are measuring power, dB =10 * Log(b/a) where a is input power and b is output power, or a is reference power and b is measured power. Note: The Bel is a seldom used unit for this reason, and is only shown to explain how the dB is derived.

Finally, the Decibel (2) So, if our amplifier puts-out 80 watts with 10 watts in, that’s: 10 * Log (80/10), or 10 * Log(8) = 9 dB Always round decibels to the nearest unit.

Decibels with Voltage When dealing with weak input signals, we often work in Volts (energy) not Watts (power). Since dB is a power ratio, we need to convert voltage to power: Since doubling the voltage quadruples the power, it’s: dB = 20 * Log(b/a)

Suffixes dB is often followed by a suffix that indicates the reference. dBi = gain relative to an imaginary isotropic antenna that radiates equally in all directions. dBd = gain relative to a dipole antenna. (0 dBd =2.15 dBi) dBm = gain relative to a milliwatt.

Adding and Subtracting 1.Gain: Just add and subtract all the gains/losses. 6 dB – 2 dB = 4 dB The total gain at the antenna is 4 dB 2.Effective Radiated Power: To convert dB to a ratio, divide it by ten, then raise 10 to that power: 10 {Yx} 0.4 = 2.5 So the output power (ERP) will effectively be 2.5 times the input power, in the desired direction. 100 * 2.5 = 250 watts ERP Let’s say we have: A 100 watt transmitter. A feedline with 2 dB loss over its length. An antenna with 6 dB gain. What is the actual gain at the antenna? What is the effective radiated power at the antenna?

Shortcuts (1) The table to the right gives the most common decibel values you need to know, and is easy to memorize. Power Decibels 2 3 4 6 8 9 10 100 20 1000 30

Shortcuts (2) The tens (the 3 in 38) place the decimal point, being the multiplier. The units (the 8 in 38) are the actual value. So 38 dB is a ratio in the 1000's and since the log of 8 is 6, it is 6000. Example, 38 dB 30 is the multiplier 08 is the value 30 = thousands 08 = 6 Therefore: 38 dB = 6000 Contributed by VE3LPX

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