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EDUCATE YOURSELF
Electronics/Electrical FAQs:
Q:
Please explain volts, amps, watts, and
C.A: That's not a question, but
okay. Volts are electrical potential,
amps are electrical current, watts are
total power equal to volts*amps, and C
is electrical current as a function of
battery capacity. Think of volts as the
width of a pipe: In general, a wider
pipe has more punch than a narrower one.
Think of amps as the water flowing
through a pipe: Some pipes can only
handle little trickles of water, and
others can handle lots of water pushing
through with great force. Think of watts
as a combination of volts (pipe width)
and amps (flow of water): A large pipe
with water flowing through really slowly
has the same output as a small pipe with
water blasting through it. This is why
high-voltage applications are preferred
over high-current applications, as a
stream of water zooming at 200mph
through a 1"-diameter pipe is much more
dangerous and difficult to maintain than
a calm, 3mph flow of water through a
4'-diameter pipe. As for C rates, that's
just a function of current draw and
battery capacity. Any power source
discharged at a 1C rate will be depleted
in 1 hour, any power source discharged
at a .25C (or C/4) rate will be depleted
in 4 hours, and so on. As an example, a
1.8Ah AA NiMH capable of an excellent
10C discharge rate can manage 1.8*10=18
amps.
Q: What are series and
parallel?
A: Series connections have
a device's positive terminal connected
to the next device's negative terminal.
This is what you get when you line up
some ordinary C-cell alkalines (for
example) end-to-end, like in a Maglite
or other flashlight. This arrangment
adds up the voltages of the cells. Such
a battery neither handles more current
nor contains more mAh capacity than a
single cell. This is the opposite of a
parallel configuration, which has
positive terminals joining together and
negative terminals joining together. An
example is those 3AA>1D adapters where
all three AA cells' positive terminals
meet at the top, and all their negative
terminals meet at the bottom. Such a
configuration has the same voltage as a
single cell, but can handle more current
draw (or contains more capacity). For
example, 1AA alk can push about 500mA at
around 1.5V for about four hours. 2AA
alks in series can push 500mA at around
3V for about four hours. 2AA alks in
parallel can push 1000mA at around 1.5V
for about four hours (or 500mA for eight
hours, and so on).
Q: What are
"direct drive" and "regulated"?
A: A
direct drive (DD) light is one that has
the battery directly connected to the
bulb or LED. A regulated light has some
sort of driver circuitry between the
two. A DD setup is heavily affected by
the battery size and type. In a
regulated light, the circuitry will try
to minimize the effects of the battery.
The huge majority of incandescent lights
are DD. They start out bright, then fade
over time. The effect is greatest with
alkalines, which don't do well in many
situations. The effect is least
noticable with Lithium-Ions, which
maintain a steady voltage under
relatively heavy loads. This is why
traditional Maglites, which are DD by
alkalines, start out bright for about
half an hour, then quickly fade out and
become dim for the next few hours until
the battery gives up. One example of a
regulated incan, which provides
rock-steady output for the majority of
the battery life, is Surefire's A2. In
order to drive mostly similar LEDs with
wildly different battery solutions, a
regulation circuit allows steady output
for as long as the battery has power. As
an example, the Fenix E0 runs on a
single AAA alkaline for eight hours with
no decrease in output. If it were DD, it
wouldn't light up at all, much less
provide constant output. An
appropriately DD LED flashlight would be
one driven by button or coin cells at
somewhere above the LED's Vf. This
results in a long runtime with slowly
decreasing output, determined by the
battery's remaining power.
Q:
What are "boost" and "buck"?
A: Boost
and buck circuits increase and decrease,
respectively, the output voltage of a
battery. This is used because of Vf
requirements (discussed elsewhere in the
Welcome Mat). Such a circuit will
usually have battery + and - inputs as
well as LED + and - outputs. The
interesting thing about these circuits
is that they can also be used to tweak
battery current consumption, as a boost
circuit will draw more current from the
battery than is flowing at the output,
and a buck circuit will draw less
current from the battery than is flowing
at the output. This generally means that
boost circuits are hard on cells, while
buck circuits are easier on them.
For example, 2AA NiMH powering an
XR-E with a Vf of 3.7V at 700mA would
require a boost circuit. If the circuit
was 100% efficient (not actually
achievable), the following equation
would apply:
3.7V/2.4V*700mA=
~1080mA
This means that we can
use a lower voltage source like 2.4V,
but we will have to draw over 1A to
produce the desired 700mA at the
emitter.
For real-life circuits
with efficiencies under 100%, simply
divide the required battery current by
the efficiency (expressed as a number
between 0 and 1). For example, an 85%
efficient boost circuit applied to the
above situation would result in the
following equation:
1080mA/0.9=
~1270mA
For buck circuits, the
opposite situation applies. For example,
powering a 5mm LED with a Vf of 3.4V at
20mA with a 90% efficient buck circuit
on a 9V battery would result in the
following equation:
3.4V/9V*20mA/.9= ~8.4mA
Keep in
mind that these are simplified
situations, with real flashlights being
influenced by a number of limiting
factors. <<
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